This is a complete list of the parameters which can be set via the MAVLink protocol in the EEPROM of your autopilot to control vehicle behaviour. This list is automatically generated from the latest ardupilot source code, and so may contain parameters which are not yet in the stable released versions of the code.
[toc exclude="Complete Parameter List"]This value is incremented when changes are made to the eeprom format
Throttle filter cutoff (Hz) - active whenever altitude control is inactive - 0 to disable
Bitmask containing various throttle stick options. TX with sprung throttle can set PILOT_THR_BHV to "1" so motor feedback when landed starts from mid-stick instead of bottom of stick.
bitmask of PIDs to send MAVLink PID_TUNING messages for
Controls whether failsafe will be invoked (and what action to take) when connection with Ground station is lost for at least 5 seconds. See FS_OPTIONS param for additional actions, or for cases allowing Mission continuation, when GCS failsafe is enabled.
| Value | Meaning |
|---|---|
| 0 | Disabled/NoAction |
| 5 | Land |
GPS Hdop value at or below this value represent a good position. Used for pre-arm checks
The throttle failsafe allows you to configure a software failsafe activated by a setting on the throttle input channel
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 3 | Enabled always Land |
The PWM level in microseconds on channel 3 below which throttle failsafe triggers
The deadzone above and below mid throttle in PWM microseconds. Used in AltHold, Loiter, PosHold flight modes
Flight mode when Channel 5 pwm is <= 1230
| Value | Meaning |
|---|---|
| 0 | LAND |
| 1 | MANUAL |
| 2 | VELOCITY |
| 3 | LOITER |
Flight mode when Channel 5 pwm is >1230, <= 1360
| Value | Meaning |
|---|---|
| 0 | LAND |
| 1 | MANUAL |
| 2 | VELOCITY |
| 3 | LOITER |
Flight mode when Channel 5 pwm is >1360, <= 1490
| Value | Meaning |
|---|---|
| 0 | LAND |
| 1 | MANUAL |
| 2 | VELOCITY |
| 3 | LOITER |
Flight mode when Channel 5 pwm is >1490, <= 1620
| Value | Meaning |
|---|---|
| 0 | LAND |
| 1 | MANUAL |
| 2 | VELOCITY |
| 3 | LOITER |
Flight mode when Channel 5 pwm is >1620, <= 1749
| Value | Meaning |
|---|---|
| 0 | LAND |
| 1 | MANUAL |
| 2 | VELOCITY |
| 3 | LOITER |
Flight mode when Channel 5 pwm is >=1750
| Value | Meaning |
|---|---|
| 0 | LAND |
| 1 | MANUAL |
| 2 | VELOCITY |
| 3 | LOITER |
RC Channel to use for flight mode control
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 5 | Channel5 |
| 6 | Channel6 |
| 7 | Channel7 |
| 8 | Channel8 |
This selects the mode to start in on boot.
| Value | Meaning |
|---|---|
| 0 | LAND |
| 1 | MANUAL |
| 2 | VELOCITY |
| 3 | LOITER |
Bitmap of what log types to enable in on-board logger. This value is made up of the sum of each of the log types you want to be saved. On boards supporting microSD cards or other large block-storage devices it is usually best just to enable all basic log types by setting this to 65535.
Delay before automatic disarm in seconds. A value of zero disables auto disarm.
Controls the action that will be taken when an EKF failsafe is invoked
| Value | Meaning |
|---|---|
| 1 | Land |
| 3 | Land even in MANUAL |
Allows setting the maximum acceptable compass and velocity variance
| Value | Meaning |
|---|---|
| 0.6 | Strict |
| 0.8 | Default |
| 1.0 | Relaxed |
This enables automatic crash checking. When enabled the motors will disarm if a crash is detected.
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
Sets the maximum XY velocity, in m/s
Sets the maximum Z velocity, in m/s
Sets the maximum yaw velocity, in rad/s
Sets the maximum XY position change, in m/s
Sets the maximum Z position change, in m/s
Sets the maximum Yaw position change, in rad/s
Simple mode for Position control - "forward" moves blimp in +ve X direction world-frame
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
Mask for disabling (setting to zero) one or more of the 4 output axis in mode Velocity or Loiter
Output 0 thrust signal when blimp is within this distance (in meters) of the target position. Warning: If this param is greater than MAX_POS_XY param then the blimp won't move at all in the XY plane in Loiter mode as it does not allow more than a second's lag. Same for the other axes.
This is the speed in Hertz that your ESCs will receive updates
Velocity (horizontal) P gain. Converts the difference between desired and actual velocity to a target acceleration
Velocity (horizontal) I gain. Corrects long-term difference between desired and actual velocity to a target acceleration
Velocity (horizontal) D gain. Corrects short-term changes in velocity
Velocity (horizontal) integrator maximum. Constrains the target acceleration that the I gain will output
Velocity (horizontal) input filter. This filter (in Hz) is applied to the input for P and I terms
Velocity (horizontal) input filter. This filter (in Hz) is applied to the input for D term
Velocity (horizontal) feed forward gain. Converts the difference between desired velocity to a target acceleration
Velocity (vertical) P gain. Converts the difference between desired and actual velocity to a target acceleration
Velocity (vertical) I gain. Corrects long-term difference between desired and actual velocity to a target acceleration
Velocity (vertical) D gain. Corrects short-term changes in velocity
Velocity (vertical) integrator maximum. Constrains the target acceleration that the I gain will output
Velocity (vertical) input filter. This filter (in Hz) is applied to the input for P and I terms
Velocity (vertical) input filter. This filter (in Hz) is applied to the input for D term
Velocity (vertical) feed forward gain. Converts the difference between desired velocity to a target acceleration
Velocity (yaw) P gain. Converts the difference between desired and actual velocity to a target acceleration
Velocity (yaw) I gain. Corrects long-term difference between desired and actual velocity to a target acceleration
Velocity (yaw) D gain. Corrects short-term changes in velocity
Velocity (yaw) integrator maximum. Constrains the target acceleration that the I gain will output
Velocity (yaw) input filter. This filter (in Hz) is applied to the input for P and I terms
Velocity (yaw) feed forward gain. Converts the difference between desired velocity to a target acceleration
Position (horizontal) P gain. Converts the difference between desired and actual position to a target velocity
Position (horizontal) I gain. Corrects long-term difference between desired and actual position to a target velocity
Position (horizontal) D gain. Corrects short-term changes in position
Position (horizontal) integrator maximum. Constrains the target acceleration that the I gain will output
Position (horizontal) input filter. This filter (in Hz) is applied to the input for P and I terms
Position (horizontal) input filter. This filter (in Hz) is applied to the input for D term
Position (horizontal) feed forward gain. Converts the difference between desired position to a target velocity
Position (vertical) P gain. Converts the difference between desired and actual position to a target velocity
Position (vertical) I gain. Corrects long-term difference between desired and actual position to a target velocity
Position (vertical) D gain. Corrects short-term changes in position
Position (vertical) integrator maximum. Constrains the target acceleration that the I gain will output
Position (vertical) input filter. This filter (in Hz) is applied to the input for P and I terms
Position (vertical) input filter. This filter (in Hz) is applied to the input for D term
Position (vertical) feed forward gain. Converts the difference between desired position to a target velocity
Position (yaw) axis controller P gain.
Position (yaw) axis controller I gain.
Position (yaw) axis controller I gain maximum.
Position (yaw) axis controller D gain.
Position (yaw) axis controller feed forward
Position (yaw) target frequency filter in Hz
Position (yaw) error frequency filter in Hz
Position (yaw) derivative input filter in Hz
Sets an upper limit on the slew rate produced by the combined P and D gains.
Position (yaw) axis controller PD sum maximum. The maximum/minimum value that the sum of the P and D term can output
FF D Gain which produces an output that is proportional to the rate of change of the target
Position (yaw) Target notch filter index
Position (yaw) Error notch filter index
Bitmask of developer options. The meanings of the bit fields in this parameter may vary at any time. Developers should check the source code for current meaning
Controls major frame class for blimp.
| Value | Meaning |
|---|---|
| 0 | Finnedblimp |
The maximum vertical descending velocity the pilot may request in cm/s
This enables the vibration failsafe which will use modified altitude estimation and control during high vibrations
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
Bitmask of additional options for battery, radio, & GCS failsafes. 0 (default) disables all options.
Timeout before triggering the GCS failsafe
Video stream camera model
| Value | Meaning |
|---|---|
| 0 | Unknown |
| 1 | Siyi A8 |
| 2 | Siyi ZR10 |
| 3 | Siyi ZR30 |
| 4 | Siyi ZT30 Zoom |
| 5 | Siyi ZT30 Wide |
| 6 | Siyi ZT30 IR |
| 7 | Siyi ZT6 RGB |
| 8 | Siyi ZT6 IR |
| 9 | Herelink WifiAP |
| 10 | Herelink USB-tethering |
| 11 | Topotek 1080p |
| 12 | Topotek 480p |
| 13 | Viewpro |
Video stream id
Video stream type
| Value | Meaning |
|---|---|
| 0 | RTSP |
| 1 | RTPUDP |
| 2 | TCP_MPEG |
| 3 | MPEG_TS |
Video stream flags
Video stream frame rate
Video stream horizontal resolution
Video stream vertical resolution
Video stream bitrate
Video stream horizontal FOV
Video stream encoding
| Value | Meaning |
|---|---|
| 0 | Unknown |
| 1 | H264 |
| 2 | H265 |
Video stream IP Address first octet
Video stream IP Address second octet
Video stream IP Address third octet
Video stream IP Address fourth octet
Video stream IP Address Port
enable battery info support
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
max battery cycles for arming
this is the highest value for battery cycles for all connected batteries
Follow Target Send Enable
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
MAVLink channel to which FOLLOW_TARGET should be sent
Maximum rate when retracting line
Maximum rate when releasing line
RCn_OPTION number to use to control winch rate
| Value | Meaning |
|---|---|
| 300 | Scripting1 |
| 301 | Scripting2 |
| 302 | Scripting3 |
| 303 | Scripting4 |
| 304 | Scripting5 |
| 305 | Scripting6 |
| 306 | Scripting7 |
| 307 | Scripting8 |
The altitude (rangefinder distance) below which we stop using the precision landing sensor and continue landing
The distance from target beyond which the target is ignored
Slung Payload enable
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
Slung Payload Velocity P gain, higher values will result in faster movements in sync with payload
Oscillation is suppressed when vehicle and payload are no more than this distance horizontally. Set to 0 to always suppress
Slung Payload mavlink system id. 0 to use any/all system ids
WP position P gain. higher values will result in vehicle moving more quickly back to the original waypoint
payload's position estimator's time constant used to compensate for GPS errors and wind. Higher values result in smoother estimate but slower response
Slung payload debug output, set to 1 to enable debug
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
The ratio between the front and back motor outputs during steady-state hover. Positive when the CoG is in front of the motors midpoint (front motors work harder).
Enable quicktune system
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
axes to tune
Ratio between measured response and FF gain. Raise this to get a higher FF gain
Ratio between steering FF and P gains. Raise this to get a higher P gain, 0 to leave P unchanged
Ratio between steering FF and I gains. Raise this to get a higher I gain, 0 to leave I unchanged
Ratio between measured response and CRUISE_THROTTLE value. Raise this to get a higher CRUISE_THROTTLE value
Ratio between speed FF and P gain. Raise this to get a higher P gain, 0 to leave P unchanged
Ratio between speed FF and I gain. Raise this to get a higher I gain, 0 to leave I unchanged
When enabled the PID filter settings are automatically set based on INS_GYRO_FILTER
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
Number of seconds after completion of tune to auto-save. This is useful when using a 2 position switch for quicktune
RCn_OPTION number to use to control tuning stop/start/save
| Value | Meaning |
|---|---|
| 300 | Scripting1 |
| 301 | Scripting2 |
| 302 | Scripting3 |
| 303 | Scripting4 |
| 304 | Scripting5 |
| 305 | Scripting6 |
| 306 | Scripting7 |
| 307 | Scripting8 |
The mimimum speed in m/s required for tuning to start
thermal image colour palette
| Value | Meaning |
|---|---|
| -1 | Leave Unchanged |
| 0 | WhiteHot |
| 2 | Sepia |
| 3 | IronBow |
| 4 | Rainbow |
| 5 | Night |
| 6 | Aurora |
| 7 | RedHot |
| 8 | Jungle |
| 9 | Medical |
| 10 | BlackHot |
| 11 | GloryHot |
thermal image temperature range
| Value | Meaning |
|---|---|
| -1 | Leave Unchanged |
| 0 | LowGain (50C to 550C) |
| 1 | HighGain (-20C to 150C) |
save images with raw temperatures
| Value | Meaning |
|---|---|
| -1 | Leave Unchanged |
| 0 | Disabled (30fps) |
| 1 | Enabled (25 fps) |
ExternalNav may be used if innovations are below this threshold
ExternalNav may be used if quality is above this threshold
OpticalFlow may be used if innovations are below this threshold
OpticalFlow may be used if quality is above this threshold
OpticalFlow may be used if rangefinder distance is below this threshold
enable web server
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
web server TCP port
web server debugging
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
web server block size for download
timeout for inactive connections
sendfile is an offloading mechanism for faster file download. If this is non-zero and the file is larger than this size then sendfile will be used for file download
Setting an RC channel's _OPTION to this value will use it for Terrain Avoidance enable/disable
If the downward distance is less than this value then start Pitching up to gain altitude.
If the farwardward distance is less than this value then start Pitching up to gain altitude.
If the downward distance is less than this value then start Quading up to gain altitude.
If the farwardward distance is less than this value then start Quading up to gain altitude.
Minimum Groundspeed (not airspeed) to be flying for Pitching to be used.
Minimum down or forward distance must be triggered for more than this many seconds to start Pitching
Terrain avoidance will not be applied if the vehicle is less than this distance from home
This is a limit on how high the terrain avoidane will take the vehicle. It acts a failsafe to prevent vertical flyaways.
This is a limit on how fast in groundspeeed terrain avoidance will take the vehicle. This is to allow for reliable sensor readings. -1 for disabled.
This is the limit for triggering airbrake to slow groundspeed as a difference between the airspeed and groundspeed. -1 for disabled.
The minimum Height above terrain to maintain when following an AUTO mission or RTL. If zero(0) use TA_PTCH_DOW_MIN.
Whether to enable Can't Make That Climb while running Terrain Avoidance
Avoidance processing rate
Use this radius for the loiter when trying to gain altitude. If not set or <=0 use WP_LOITER_RAD
enable Auto land script action
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
Altitude of final approach waypoint created by script
Distance from landing point (HOME) to final approach waypoint created by script in the opposite direction of initial takeoff
AHRS/EKF origin will be set to this latitude if not already set
AHRS/EKF origin will be set to this longitude if not already set
AHRS/EKF origin will be set to this altitude (in meters above sea level) if not already set
Enable quicktune system
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
axes to tune
Time to double a tuning parameter. Raise this for a slower tune.
Reduction in gain after oscillation detected. Raise this number to get a more conservative tune
Threshold for oscillation detection. A lower value will lead to a more conservative tune.
Maximum value for yaw P gain
Maximum value for yaw D gain
Ratio between P and I gains for roll and pitch. Raise this to get a lower I gain
Ratio between P and I gains for yaw. Raise this to get a lower I gain
When enabled the PID filter settings are automatically set based on INS_GYRO_FILTER
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
Number of seconds after completion of tune to auto-save. This is useful when using a 2 position switch for quicktune
RCn_OPTION number to use to control tuning stop/start/save
This controls how much quicktune is allowed to lower gains from the original gains. If the vehicle already has a reasonable tune and is not oscillating then you can set this to zero to prevent gain reductions. The default of 20% is reasonable for most vehicles. Using a maximum gain reduction lowers the chance of an angle P oscillation happening if quicktune gets a false positive oscillation at a low gain, which can result in very low rate gains and a dangerous angle P oscillation.
Additional options. When the Two Position Switch option is enabled then a high switch position will start the tune, low will disable the tune. you should also set a QUIK_AUTO_SAVE time so that you will be able to save the tune.
If while tuning the angle error goes over this limit then the tune will aborts to prevent a bad oscillation in the case of the tuning algorithm failing. If you get an error "Tuning: attitude error ABORTING" and you think it is a false positive then you can either raise this parameter or you can try increasing the QUIK_DOUBLE_TIME to do the tune more slowly. A value of zero disables this check.
Enable parameter reversion system
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
RCn_OPTION number to used to trigger parameter reversion
Automatically enables High Latency mode if not already enabled
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
| 2 | Enabled on telemetry loss |
When in High Latency mode, send Rockblock updates every N seconds
Sends Rockblock debug text to GCS via statustexts
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
Enables the Rockblock sending and recieving
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
If RCK_FORCEHL=2, this is the number of seconds of GCS timeout until High Latency mode is auto-enabled
POI's max distance (in meters) from the vehicle
Check that MAV_SYSID (or SYDID_THISMAV) has been set. 3 or less to prevent arming. -1 to disable.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 0 | Emergency(PreArm) |
| 1 | Alert(PreArm) |
| 2 | Critical(PreArm) |
| 3 | Error(PreArm) |
| 4 | Warning |
| 5 | Notice |
| 6 | Info |
| 7 | Debug |
If FOLL_ENABLE = 1, check that FOLL_SYSID has been set. 3 or less to prevent arming. -1 to disable.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 0 | Emergency(PreArm) |
| 1 | Alert(PreArm) |
| 2 | Critical(PreArm) |
| 3 | Error(PreArm) |
| 4 | Warning |
| 5 | Notice |
| 6 | Info |
| 7 | Debug |
If FOLL_ENABLE = 1, check that FOLL_SYSID is different to MAV_SYSID. 3 or less to prevent arming. -1 to disable.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 0 | Emergency(PreArm) |
| 1 | Alert(PreArm) |
| 2 | Critical(PreArm) |
| 3 | Error(PreArm) |
| 4 | Warning |
| 5 | Notice |
| 6 | Info |
| 7 | Debug |
Follow offsets should not be left as default (zero) if FOLL_ENABLE = 1. 3 or less to prevent arming. -1 to disable.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 0 | Emergency(PreArm) |
| 1 | Alert(PreArm) |
| 2 | Critical(PreArm) |
| 3 | Error(PreArm) |
| 4 | Warning |
| 5 | Notice |
| 6 | Info |
| 7 | Debug |
If FOLL_ENABLE = 1 and MNTx_SYSID_DEFLT is set, check that FOLL_SYSID is equal MNTx. 3 or less to prevent arming. -1 to disable.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 0 | Emergency(PreArm) |
| 1 | Alert(PreArm) |
| 2 | Critical(PreArm) |
| 3 | Error(PreArm) |
| 4 | Warning |
| 5 | Notice |
| 6 | Info |
| 7 | Debug |
RTL_CLIMB_MIN should be < 120m (400ft). 3 or less to prevent arming. -1 to disable.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 0 | Emergency(PreArm) |
| 1 | Alert(PreArm) |
| 2 | Critical(PreArm) |
| 3 | Error(PreArm) |
| 4 | Warning |
| 5 | Notice |
| 6 | Info |
| 7 | Debug |
Emergency Stop disables arming. 3 or less to prevent arming. -1 to disable.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 0 | Emergency(PreArm) |
| 1 | Alert(PreArm) |
| 2 | Critical(PreArm) |
| 3 | Error(PreArm) |
| 4 | Warning |
| 5 | Notice |
| 6 | Info |
| 7 | Debug |
Fences loaded but no fence enabled. 3 or less to prevent arming. -1 to disable.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 0 | Emergency(PreArm) |
| 1 | Alert(PreArm) |
| 2 | Critical(PreArm) |
| 3 | Error(PreArm) |
| 4 | Warning |
| 5 | Notice |
| 6 | Info |
| 7 | Debug |
Rally Point more than RALLY_LIMIT_KM kilometers away. 3 or less to prevent arming. -1 to disable.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 0 | Emergency(PreArm) |
| 1 | Alert(PreArm) |
| 2 | Critical(PreArm) |
| 3 | Error(PreArm) |
| 4 | Warning |
| 5 | Notice |
| 6 | Info |
| 7 | Debug |
RTL_ALT should be < 120m (400ft). 3 or less to prevent arming. -1 to disable.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 0 | Emergency(PreArm) |
| 1 | Alert(PreArm) |
| 2 | Critical(PreArm) |
| 3 | Error(PreArm) |
| 4 | Warning |
| 5 | Notice |
| 6 | Info |
| 7 | Debug |
Notify the user that on failsafe a QuadPlan will land. 3 or less to prevent arming. -1 to disable.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 0 | Emergency(PreArm) |
| 1 | Alert(PreArm) |
| 2 | Critical(PreArm) |
| 3 | Error(PreArm) |
| 4 | Warning |
| 5 | Notice |
| 6 | Info |
| 7 | Debug |
Notify the user that on failsafe a QuadPlan will QRTL. 3 or less to prevent arming. -1 to disable.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 0 | Emergency(PreArm) |
| 1 | Alert(PreArm) |
| 2 | Critical(PreArm) |
| 3 | Error(PreArm) |
| 4 | Warning |
| 5 | Notice |
| 6 | Info |
| 7 | Debug |
Validate that AIRSPEED_STALL(if set) < MIN < CRUISE < MAX d. 3 or less to prevent arming. -1 to disable.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 0 | Emergency(PreArm) |
| 1 | Alert(PreArm) |
| 2 | Critical(PreArm) |
| 3 | Error(PreArm) |
| 4 | Warning |
| 5 | Notice |
| 6 | Info |
| 7 | Debug |
Validate that AIRSPEED_MIN is at least 25% above AIRSPEED_STALL(if set). 3 or less to prevent arming. -1 to disable.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 0 | Emergency(PreArm) |
| 1 | Alert(PreArm) |
| 2 | Critical(PreArm) |
| 3 | Error(PreArm) |
| 4 | Warning |
| 5 | Notice |
| 6 | Info |
| 7 | Debug |
Validate that SCALING_SPEED is within 20% of AIRSPEED_CRUISE. If SCALING_SPEED changes the vehicle may need to be retuned. 3 or less to prevent arming. -1 to disable.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 0 | Emergency(PreArm) |
| 1 | Alert(PreArm) |
| 2 | Critical(PreArm) |
| 3 | Error(PreArm) |
| 4 | Warning |
| 5 | Notice |
| 6 | Info |
| 7 | Debug |
RTL_ALTITITUDE should be < 120m (400ft). 3 or less to prevent arming. -1 to disable.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 0 | Emergency(PreArm) |
| 1 | Alert(PreArm) |
| 2 | Critical(PreArm) |
| 3 | Error(PreArm) |
| 4 | Warning |
| 5 | Notice |
| 6 | Info |
| 7 | Debug |
Q_RTL_ALT should be < 120m (400ft). 3 or less to prevent arming. -1 to disable.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 0 | Emergency(PreArm) |
| 1 | Alert(PreArm) |
| 2 | Critical(PreArm) |
| 3 | Error(PreArm) |
| 4 | Warning |
| 5 | Notice |
| 6 | Info |
| 7 | Debug |
Legal max altitude for UAV/RPAS/drones in your jurisdiction
terrain brake enable
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
terrain brake altitude. The altitude above the ground below which BRAKE mode will be engaged if in LOITER mode.
terrain brake home distance. The distance from home where the auto BRAKE will be enabled. When within this distance of home the script will not activate
terrain brake speed threshold. Don't trigger BRAKE if both horizontal speed and descent rate are below this threshold. By setting this to a small value this can be used to allow the user to climb up to a safe altitude in LOITER mode. A value of 0.5 is recommended if you want to use LOITER to recover from an emergency terrain BRAKE mode change.
Deadreckoning Enable
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
Distance from home (in meters) beyond which the dead reckoning will be enabled
GPS speed accuracy maximum, above which deadreckoning home will begin (default is 0.8). Lower values trigger with good GPS quality, higher values will allow poorer GPS before triggering. Set to 0 to disable use of GPS speed accuracy
GPS satellite count threshold below which deadreckoning home will begin (default is 6). Higher values trigger with good GPS quality, Lower values trigger with worse GPS quality. Set to 0 to disable use of GPS satellite count
GPS checks must fail for this many seconds before dead reckoning will be triggered
lean angle (in degrees) during deadreckoning
Copter will fly at at least this altitude (in meters) above home during deadreckoning
Copter will attempt to switch to NEXT_MODE after this many seconds of deadreckoning. If it cannot switch modes it will continue in Guided_NoGPS. Set to 0 to disable timeout
Copter switch to this mode after GPS recovers or DR_FLY_TIMEOUT has elapsed. Default is 6/RTL. Set to -1 to return to mode used before deadreckoning was triggered
| Value | Meaning |
|---|---|
| 2 | AltHold |
| 3 | Auto |
| 4 | Guided |
| 5 | Loiter |
| 6 | RTL |
| 7 | Circle |
| 9 | Land |
| 16 | PosHold |
| 17 | Brake |
| 20 | Guided_NoGPS |
| 21 | Smart_RTL |
| 27 | Auto RTL |
Param Set enable
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
Number of battery SOC estimators
Battery estimator index
Battery estimator cell count
Battery estimator coefficient1
Battery estimator coefficient2
Battery estimator coefficient3
Battery estimator coefficient4
Battery estimator index
Battery estimator cell count
Battery estimator coefficient1
Battery estimator coefficient2
Battery estimator coefficient3
Battery estimator coefficient4
Battery estimator index
Battery estimator cell count
Battery estimator coefficient1
Battery estimator coefficient2
Battery estimator coefficient3
Battery estimator coefficient4
Battery estimator index
Battery estimator cell count
Battery estimator coefficient1
Battery estimator coefficient2
Battery estimator coefficient3
Battery estimator coefficient4
Enable ship landing system
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
Angle from the stern of the ship for landing approach. Use this to ensure that on a go-around that ship superstructure and cables are avoided. A value of zero means to approach from the rear of the ship. A value of 90 means the landing will approach from the port (left) side of the ship. A value of -90 will mean approaching from the starboard (right) side of the ship. A value of 180 will approach from the bow of the ship. This parameter is combined with the sign of the RTL_RADIUS parameter to determine the holdoff pattern. If RTL_RADIUS is positive then a clockwise loiter is performed, if RTL_RADIUS is negative then a counter-clockwise loiter is used.
Settings this parameter to one triggers an automatic follow offset calculation based on current position of the vehicle and the landing target. NOTE: This parameter will auto-reset to zero once the offset has been calculated.
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Trigger |
Maximum angular acceleration in maneuvers
This is the time over which we filter the desired roll to smooth it
This controls how much extra throttle to add based on pitch ange. The value is for 90 degrees and is applied in proportion to pitch
This controls how rapidly the throttle is raised to compensate for a speed error
This controls how rapidly the throttle is raised to compensate for a speed error
This is the time constant for correcting roll errors. A smaller value leads to faster roll corrections
This is the time constant for correcting path position errors
This controls how rapidly we correct back onto the desired path
This controls how rapidly we correct back onto the desired path
This controls how rapidly we roll into a new orientation
This controls how far ahead we look in time along the path for the target throttle
This controls the printing of extra debug information on paths
Lowest throttle used during maneuvers
This is the extra throttle added in schedule elements marked as needing a throttle boost
This is maximum yaw acceleration to use
This is how much time to look ahead in the path for calculating path rates
Scale factor for Path/Box size. 0.5 would half the distances in maneuvers. Radii are unaffected.
Length of aerobatic "box"
Amount of throttle to reduce to for a stall turn
Pitch threashold for moving to final stage of stall turn
Percent of rudder normally uses to sustain knife-edge at trick speed
Time to look ahead in the path to calculate rudder correction for bank angle
Maximum allowable loss in altitude during a trick or sequence from its starting altitude.
This controls how rapidly two aircraft are brought back into time sync
This controls how rapidly two aircraft are brought back into time sync
This sets the maximum speed adjustment for time sync between aircraft
This sets the rate we send data for time sync between aircraft
When set to a non-zero value, this is the assumed direction of the mission. Otherwise the waypoint angle is used
Options to control aerobatic behavior
Enables Tricks on Switch. TRIK params hidden until enabled
Setting an RC channel's _OPTION to this value will use it for trick selection
Setting an RC channel's _OPTION to this value will use it for trick action (abort,announce,execute)
Number of tricks which can be selected over the range of the trik selection RC channel
Enable HFE EFI driver
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
HFI EFI Update rate
HFI EFI ECU index, 0 for automatic
HFI EFI fuel density in gram per litre
HFI EFI relay index
HFI EFI CAN driver
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | 1stCANDriver |
| 2 | 2ndCanDriver |
HFI EFI options
Enable Halo6000 EFI driver
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
Halo6000 CAN driver. Use 1 for first CAN scripting driver, 2 for 2nd driver
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | FirstCAN |
| 2 | SecondCAN |
The RC auxilliary function number for start/stop of the generator. Zero to disable start function
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 300 | 300 |
| 301 | 301 |
| 302 | 302 |
| 303 | 303 |
| 304 | 304 |
| 305 | 305 |
| 306 | 306 |
| 307 | 307 |
The rate that additional generator telemetry is sent
The capacity of the tank in litres
Halo6000 options
Mask of UltraMotion servos
Set CAN driver
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | 1stCANDriver |
| 2 | 2ndCanDriver |
Update rate for UltraMotion servos
Optional settings
ViewPro debug
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
| 2 | Enabled including attitude reporting |
Camera selection when switch is in low position
| Value | Meaning |
|---|---|
| 0 | No change in camera selection |
| 1 | EO1 |
| 2 | IR thermal |
| 3 | EO1 + IR Picture-in-picture |
| 4 | IR + EO1 Picture-in-picture |
| 5 | Fusion |
| 6 | IR1 13mm |
| 7 | IR2 52mm |
Camera selection when switch is in middle position
| Value | Meaning |
|---|---|
| 0 | No change in camera selection |
| 1 | EO1 |
| 2 | IR thermal |
| 3 | EO1 + IR Picture-in-picture |
| 4 | IR + EO1 Picture-in-picture |
| 5 | Fusion |
| 6 | IR1 13mm |
| 7 | IR2 52mm |
Camera selection when switch is in high position
| Value | Meaning |
|---|---|
| 0 | No change in camera selection |
| 1 | EO1 |
| 2 | IR thermal |
| 3 | EO1 + IR Picture-in-picture |
| 4 | IR + EO1 Picture-in-picture |
| 5 | Fusion |
| 6 | IR1 13mm |
| 7 | IR2 52mm |
ViewPro Zoom Speed. Higher numbers result in faster zooming
ViewPro Zoom Times Max
Enable NMEA 2000 EFI driver
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
NMEA 2000 CAN driver. Use 1 for first CAN scripting driver, 2 for 2nd driver
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | FirstCAN |
| 2 | SecondCAN |
NMEA 2000 driver options
Enable DJIRS2 debug
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
| 2 | Enabled with attitude reporting |
DJIRS2 upside down
| Value | Meaning |
|---|---|
| 0 | Right side up |
| 1 | Upside down |
Enable SkyPower EFI support
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
Set SkyPower EFI CAN driver
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | 1stCANDriver |
| 2 | 2ndCanDriver |
SkyPower EFI update rate
SkyPower EFI throttle function. This sets which SERVOn_FUNCTION to use for the target throttle. This should be 70 for fixed wing aircraft and 31 for helicopter rotor speed control
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 70 | FixedWing |
| 31 | HeliRSC |
SkyPower EFI throttle rate. This sets rate at which throttle updates are sent to the engine
SkyPower EFI start function. This is the RCn_OPTION value to use to find the R/C channel used for controlling engine start
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 300 | 300 |
| 301 | 301 |
| 302 | 302 |
| 303 | 303 |
| 304 | 304 |
| 305 | 305 |
| 306 | 306 |
| 307 | 307 |
SkyPower EFI generator control function. This is the RCn_OPTION value to use to find the R/C channel used for controlling generator start/stop
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 300 | 300 |
| 301 | 301 |
| 302 | 302 |
| 303 | 303 |
| 304 | 304 |
| 305 | 305 |
| 306 | 306 |
| 307 | 307 |
SkyPower EFI minimum RPM. This is the RPM below which the engine is considered to be stopped
SkyPower EFI telemetry rate. This is the rate at which extra telemetry values are sent to the GCS
SkyPower EFI log rate. This is the rate at which extra logging of the SkyPower EFI is performed
SkyPower EFI allow start disarmed. This controls if starting the engine while disarmed is allowed
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
SkyPower EFI ECU model
| Value | Meaning |
|---|---|
| 0 | SRE_180 |
| 1 | SP_275 |
SkyPower EFI enable generator control
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
SkyPower EFI restart time. If engine should be running and it has stopped for this amount of time then auto-restart. To disable this feature set this value to zero.
Enable EFI DLA64 driver
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
Torqeedo TorqLink Enable
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
Torqeedo TorqLink Debug Level
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Low |
| 2 | Medium |
| 3 | High |
Enable EFI DLA driver
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
EFI DLA litres of fuel per second of injection time
Enable ANX battery support
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
Set ANX CAN driver
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | 1stCANDriver |
| 2 | 2ndCanDriver |
ANX CAN battery index
ANX CAN battery options
Enable SVFFI generator support
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
Check for Generator ARM state before arming
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
Enable EFI INF-Inject driver
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
EFI INF driver options
EFI INF throttle output rate
EFI INF throttle ignition aux function
Enable or disable the LTE modem driver
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
Serial port to use for the LTE modem. This is the index of the SERIALn_ ports that are set to 28 for "scripting"
Scripting Serial port to use for the LTE modem. This is the index of the SCR_SDEV ports that are set to 2 for "MAVLink2"
First octet of the server IP address to connect to
Second octet of the server IP address to connect to
Third octet of the server IP address to connect to
Fourth octet of the server IP address to connect to
IPv4 Port of the server to connect to
Baud rate for the serial port to the LTE modem when connected. Initial power on baudrate is in LTE_IBAUD
| Value | Meaning |
|---|---|
| 19200 | 19200 |
| 38400 | 38400 |
| 57600 | 57600 |
| 115200 | 115200 |
| 230400 | 230400 |
| 460800 | 460800 |
| 921600 | 921600 |
| 3686400 | 3686400 |
Timeout in seconds for the LTE connection. If no data is received for this time, the connection will be reset. A value of zero disables the timeout
The protocol that we will use in communication with the LTE modem. If this is PPP then the LTE_SERVER parameters are not used and instead a PPP connection will be established and you should use the NET_ parameters to enable network ports. If this is MAVLink2 then the LTE_SERVER parameters are used to create a TCP or UDP connection to a single server.
| Value | Meaning |
|---|---|
| 2 | MavLink2 |
| 48 | PPP |
Options to control the LTE modem driver. If VerboseSignalInfoGCS is set then additional NAMED_VALUE_FLOAT values are sent with verbose signal information
This is the initial baud rate on power on for the modem. This is set in the modem with the AT+IREX=baud command
| Value | Meaning |
|---|---|
| 19200 | 19200 |
| 38400 | 38400 |
| 57600 | 57600 |
| 115200 | 115200 |
| 230400 | 230400 |
| 460800 | 460800 |
| 921600 | 921600 |
| 3686400 | 3686400 |
This allows selection of network operator
| Value | Meaning |
|---|---|
| -1 | NoChange |
| 0 | Default |
| AU-Telstra | 50501 |
| AU-Optus | 50502 |
| AU-Vodaphone | 50503 |
Maximum data transmit rate to the modem in bytes/second. Use zero for unlimited
This allows selection of LTE band. A value of -1 means no band setting change is made. A value of 0 sets all bands. Otherwise the specified band is set.
Enable Hobbywing ESC telemetry
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
Number of motor poles for eRPM scaling
Motor number offset of first ESC
Set 0 if sensor is to be used as a 1-D rangefinder (minimum of all distances will be sent, typically used for height detection). Set 1 if it should be used as a 3-D proximity device (Eg. Obstacle Avoidance)
| Value | Meaning |
|---|---|
| 0 | Set as Rangefinder |
| 1 | Set as Proximity sensor |
Number of TOFSENSE-M CAN sensors connected
TOFSENSE-M mode to be used. 0 for 8x8 mode. 1 for 4x4 mode
| Value | Meaning |
|---|---|
| 0 | 8x8 mode |
| 1 | 4x4 mode |
First TOFSENSE-M sensors backend Instance. Setting this to 1 will pick the first backend from PRX_ or RNG_ Parameters (Depending on TOFSENSE_PRX)
First TOFSENSE-M sensor ID. Leave this at 0 to accept all IDs and if only one sensor is present. You can change ID of sensor from NAssistant Software
Second TOFSENSE-M sensors backend Instance. Setting this to 2 will pick the second backend from PRX_ or RNG_ Parameters (Depending on TOFSENSE_PRX)
Second TOFSENSE-M sensor ID. This cannot be 0. You can change ID of sensor from NAssistant Software
Third TOFSENSE-M sensors backend Instance. Setting this to 3 will pick the second backend from PRX_ or RNG_ Parameters (Depending on TOFSENSE_PRX)
Third TOFSENSE-M sensor ID. This cannot be 0. You can change ID of sensor from NAssistant Software
Set 0 if sensor is to be used as a 1-D rangefinder (minimum of all distances will be sent, typically used for height detection). Set 1 if it should be used as a 3-D proximity device (Eg. Obstacle Avoidance)
| Value | Meaning |
|---|---|
| 0 | Set as Rangefinder |
| 1 | Set as Proximity sensor |
UART instance sensor is connected to. Set 1 if sensor is connected to the port with fist SERIALx_PROTOCOL = 28.
Serial Port baud rate. Sensor baud rate can be changed from Nassistant software
This controls how much to use the GPS to correct the attitude. This should never be set to zero for a plane as it would result in the plane losing control in turns. For a plane please use the default value of 1.0.
This controls whether to use dead-reckoning or GPS based navigation. If set to 0 then the GPS won't be used for navigation, and only dead reckoning will be used. A value of zero should never be used for normal flight. Currently this affects only the DCM-based AHRS: the EKF uses GPS according to its own parameters. A value of 2 means to use GPS for height as well as position - both in DCM estimation and when determining altitude-above-home.
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Use GPS for DCM position |
| 2 | Use GPS for DCM position and height |
This controls the weight the compass or GPS has on the heading. A higher value means the heading will track the yaw source (GPS or compass) more rapidly.
This controls how fast the accelerometers correct the attitude
This sets the maximum allowable difference between ground speed and airspeed. A value of zero means to use the airspeed as is. This allows the plane to cope with a failing airspeed sensor by clipping it to groundspeed plus/minus this limit. See ARSPD_OPTIONS and ARSPD_WIND_MAX to disable airspeed sensors.
Compensates for the roll angle difference between the control board and the frame. Positive values make the vehicle roll right.
Compensates for the pitch angle difference between the control board and the frame. Positive values make the vehicle pitch up/back.
Not Used
Overall board orientation relative to the standard orientation for the board type. This rotates the IMU and compass readings to allow the board to be oriented in your vehicle at any 90 or 45 degree angle. The label for each option is specified in the order of rotations for that orientation. This option takes affect on next boot. After changing you will need to re-level your vehicle. Firmware versions 4.2 and prior can use a CUSTOM (100) rotation to set the AHRS_CUSTOM_ROLL/PIT/YAW angles for AHRS orientation. Later versions provide two general custom rotations which can be used, Custom 1 and Custom 2, with CUST_ROT1_ROLL/PIT/YAW or CUST_ROT2_ROLL/PIT/YAW angles.
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Yaw45 |
| 2 | Yaw90 |
| 3 | Yaw135 |
| 4 | Yaw180 |
| 5 | Yaw225 |
| 6 | Yaw270 |
| 7 | Yaw315 |
| 8 | Roll180 |
| 9 | Yaw45Roll180 |
| 10 | Yaw90Roll180 |
| 11 | Yaw135Roll180 |
| 12 | Pitch180 |
| 13 | Yaw225Roll180 |
| 14 | Yaw270Roll180 |
| 15 | Yaw315Roll180 |
| 16 | Roll90 |
| 17 | Yaw45Roll90 |
| 18 | Yaw90Roll90 |
| 19 | Yaw135Roll90 |
| 20 | Roll270 |
| 21 | Yaw45Roll270 |
| 22 | Yaw90Roll270 |
| 23 | Yaw135Roll270 |
| 24 | Pitch90 |
| 25 | Pitch270 |
| 26 | Yaw90Pitch180 |
| 27 | Yaw270Pitch180 |
| 28 | Pitch90Roll90 |
| 29 | Pitch90Roll180 |
| 30 | Pitch90Roll270 |
| 31 | Pitch180Roll90 |
| 32 | Pitch180Roll270 |
| 33 | Pitch270Roll90 |
| 34 | Pitch270Roll180 |
| 35 | Pitch270Roll270 |
| 36 | Yaw90Pitch180Roll90 |
| 37 | Yaw270Roll90 |
| 38 | Yaw293Pitch68Roll180 |
| 39 | Pitch315 |
| 40 | Pitch315Roll90 |
| 42 | Roll45 |
| 43 | Roll315 |
| 100 | Custom 4.1 and older |
| 101 | Custom 1 |
| 102 | Custom 2 |
This controls the time constant for the cross-over frequency used to fuse AHRS (airspeed and heading) and GPS data to estimate ground velocity. Time constant is 0.1/beta. A larger time constant will use GPS data less and a small time constant will use air data less.
Minimum number of satellites visible to use GPS for velocity based corrections attitude correction. This defaults to 6, which is about the point at which the velocity numbers from a GPS become too unreliable for accurate correction of the accelerometers.
This controls which NavEKF Kalman filter version is used for attitude and position estimation
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 2 | Enable EKF2 |
| 3 | Enable EKF3 |
| 10 | Sim |
| 11 | ExternalAHRS |
Autopilot mounting position roll offset. Positive values = roll right, negative values = roll left. This parameter is only used when AHRS_ORIENTATION is set to CUSTOM.
Autopilot mounting position pitch offset. Positive values = pitch up, negative values = pitch down. This parameter is only used when AHRS_ORIENTATION is set to CUSTOM.
Autopilot mounting position yaw offset. Positive values = yaw right, negative values = yaw left. This parameter is only used when AHRS_ORIENTATION is set to CUSTOM.
This controls optional AHRS behaviour. Setting DisableDCMFallbackFW will change the AHRS behaviour for fixed wing aircraft in fly-forward flight to not fall back to DCM when the EKF stops navigating. Setting DisableDCMFallbackVTOL will change the AHRS behaviour for fixed wing aircraft in non fly-forward (VTOL) flight to not fall back to DCM when the EKF stops navigating. Setting DontDisableAirspeedUsingEKF disables the EKF based innovation check for airspeed consistency
AIS receiver type
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | NMEA AIVDM message |
AIS list size of nearest vessels. Longer lists take longer to refresh with lower SRx_ADSB values.
if no updates are received in this time a vessel will be removed from the list
Bitmask of AIS logging options
Accelerometer error threshold used to determine inconsistent accelerometers. Compares this error range to other accelerometers to detect a hardware or calibration error. Lower value means tighter check and harder to pass arming check. Not all accelerometers are created equal.
Allow arm/disarm by rudder input. When enabled arming can be done with right rudder, disarming with left rudder. Rudder arming only works with throttle at zero +- deadzone (RCx_DZ). Depending on vehicle type, arming in certain modes is prevented. See the wiki for each vehicle. Caution is recommended when arming if it is allowed in an auto-throttle mode!
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | ArmingOnly |
| 2 | ArmOrDisarm |
Bitmask of mission items that are required to be planned in order to arm the aircraft
Checks prior to arming motor. This is a bitmask of checks that will be performed before allowing arming. For most users it is recommended to leave this at the default of 1 (all checks enabled). You can select whatever checks you prefer by adding together the values of each check type to set this parameter. For example, to only allow arming when you have GPS lock and no RC failsafe you would set ARMING_CHECK to 72.
Options that can be applied to change arming behaviour
Compass magnetic field strength error threshold vs earth magnetic model. X and y axis are compared using this threhold, Z axis uses 2x this threshold. 0 to disable check
Must have value "1" if crashdump data is present on the system, or a prearm failure will be raised. Do not set this parameter unless the risks of doing so are fully understood. The presence of a crash dump means that the firmware currently installed has suffered a critical software failure which resulted in the autopilot immediately rebooting. The crashdump file gives diagnostic information which can help in finding the issue, please contact the ArduPIlot support team. If this crashdump data is present, the vehicle is likely unsafe to fly. Check the ArduPilot documentation for more details.
| Value | Meaning |
|---|---|
| 0 | Crash Dump arming check active |
| 1 | Crash Dump arming check deactivated |
Enable airspeed sensor support
| Value | Meaning |
|---|---|
| 0 | Disable |
| 1 | Enable |
This parameter allows you to control whether the order in which the tubes are attached to your pitot tube matters. If you set this to 0 then the first (often the top) connector on the sensor needs to be the stagnation pressure (the pressure at the tip of the pitot tube). If set to 1 then the second (often the bottom) connector needs to be the stagnation pressure. If set to 2 (the default) then the airspeed driver will accept either order. The reason you may wish to specify the order is it will allow your airspeed sensor to detect if the aircraft is receiving excessive pressure on the static port compared to the stagnation port such as during a stall, which would otherwise be seen as a positive airspeed.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Swapped |
| 2 | Auto Detect |
This selects which airspeed sensor will be the primary if multiple sensors are found
| Value | Meaning |
|---|---|
| 0 | FirstSensor |
| 1 | 2ndSensor |
This parameter and function is not used by this vehicle. Always set to 0.
This parameter and function is not used by this vehicle. Always set to 0.
This parameter and function is not used by this vehicle. Always set to 0.
This parameter and function is not used by this vehicle.
The maximum percentage speed change in airspeed reports that is allowed due to offset changes between calibrations before a warning is issued. This potential speed error is in percent of AIRSPEED_MIN. 0 disables. Helps warn of calibrations without pitot being covered.
Type of airspeed sensor
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | I2C-MS4525D0 |
| 2 | Analog |
| 3 | I2C-MS5525 |
| 4 | I2C-MS5525 (0x76) |
| 5 | I2C-MS5525 (0x77) |
| 6 | I2C-SDP3X |
| 7 | I2C-DLVR-5in |
| 8 | DroneCAN |
| 9 | I2C-DLVR-10in |
| 10 | I2C-DLVR-20in |
| 11 | I2C-DLVR-30in |
| 12 | I2C-DLVR-60in |
| 13 | NMEA water speed |
| 14 | MSP |
| 15 | ASP5033 |
| 16 | ExternalAHRS |
| 17 | AUAV-10in |
| 18 | AUAV-5in |
| 19 | AUAV-30in |
| 100 | SITL |
This parameter is not used by this vehicle. Always set to 0.
| Value | Meaning |
|---|---|
| 0 | DoNotUse |
| 1 | Use |
| 2 | UseWhenZeroThrottle |
Airspeed calibration offset
Calibrates pitot tube pressure to velocity. Increasing this value will indicate a higher airspeed at any given dynamic pressure.
The pin number that the airspeed sensor is connected to for analog sensors. Values for some autopilots are given as examples. Search wiki for "Analog pins".
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
Enables automatic adjustment of airspeed ratio during a calibration flight based on estimation of ground speed and true airspeed. New ratio saved every 2 minutes if change is > 5%. Should not be left enabled.
This parameter allows you to control whether the order in which the tubes are attached to your pitot tube matters. If you set this to 0 then the first (often the top) connector on the sensor needs to be the stagnation pressure (the pressure at the tip of the pitot tube). If set to 1 then the second (often the bottom) connector needs to be the stagnation pressure. If set to 2 (the default) then the airspeed driver will accept either order. The reason you may wish to specify the order is it will allow your airspeed sensor to detect if the aircraft is receiving excessive pressure on the static port compared to the stagnation port such as during a stall, which would otherwise be seen as a positive airspeed.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Swapped |
| 2 | Auto Detect |
This parameter allows you to skip airspeed offset calibration on startup, instead using the offset from the last calibration or requiring a manual calibration. This may be desirable if the offset variance between flights for your sensor is low and you want to avoid having to cover the pitot tube on each boot.
| Value | Meaning |
|---|---|
| 0 | Disable |
| 1 | Do not require offset calibration before flight. Manual calibration should be performed during initial setup. |
| 2 | Do not calibrate on start up. Manual calibration must be performed once per boot. |
This parameter allows you to set the PSI (pounds per square inch) range for your sensor. You should not change this unless you examine the datasheet for your device
Bus number of the I2C bus where the airspeed sensor is connected. May not correspond to board's I2C bus number labels. Retry another bus and reboot if airspeed sensor fails to initialize.
| Value | Meaning |
|---|---|
| 0 | Bus0 |
| 1 | Bus1 |
| 2 | Bus2 |
| 3 | Bus3 |
Airspeed sensor ID, taking into account its type, bus and instance
Type of airspeed sensor
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | I2C-MS4525D0 |
| 2 | Analog |
| 3 | I2C-MS5525 |
| 4 | I2C-MS5525 (0x76) |
| 5 | I2C-MS5525 (0x77) |
| 6 | I2C-SDP3X |
| 7 | I2C-DLVR-5in |
| 8 | DroneCAN |
| 9 | I2C-DLVR-10in |
| 10 | I2C-DLVR-20in |
| 11 | I2C-DLVR-30in |
| 12 | I2C-DLVR-60in |
| 13 | NMEA water speed |
| 14 | MSP |
| 15 | ASP5033 |
| 16 | ExternalAHRS |
| 17 | AUAV-10in |
| 18 | AUAV-5in |
| 19 | AUAV-30in |
| 100 | SITL |
This parameter is not used by this vehicle. Always set to 0.
| Value | Meaning |
|---|---|
| 0 | DoNotUse |
| 1 | Use |
| 2 | UseWhenZeroThrottle |
Airspeed calibration offset
Calibrates pitot tube pressure to velocity. Increasing this value will indicate a higher airspeed at any given dynamic pressure.
The pin number that the airspeed sensor is connected to for analog sensors. Values for some autopilots are given as examples. Search wiki for "Analog pins".
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
Enables automatic adjustment of airspeed ratio during a calibration flight based on estimation of ground speed and true airspeed. New ratio saved every 2 minutes if change is > 5%. Should not be left enabled.
This parameter allows you to control whether the order in which the tubes are attached to your pitot tube matters. If you set this to 0 then the first (often the top) connector on the sensor needs to be the stagnation pressure (the pressure at the tip of the pitot tube). If set to 1 then the second (often the bottom) connector needs to be the stagnation pressure. If set to 2 (the default) then the airspeed driver will accept either order. The reason you may wish to specify the order is it will allow your airspeed sensor to detect if the aircraft is receiving excessive pressure on the static port compared to the stagnation port such as during a stall, which would otherwise be seen as a positive airspeed.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Swapped |
| 2 | Auto Detect |
This parameter allows you to skip airspeed offset calibration on startup, instead using the offset from the last calibration or requiring a manual calibration. This may be desirable if the offset variance between flights for your sensor is low and you want to avoid having to cover the pitot tube on each boot.
| Value | Meaning |
|---|---|
| 0 | Disable |
| 1 | Do not require offset calibration before flight. Manual calibration should be performed during initial setup. |
| 2 | Do not calibrate on start up. Manual calibration must be performed once per boot. |
This parameter allows you to set the PSI (pounds per square inch) range for your sensor. You should not change this unless you examine the datasheet for your device
Bus number of the I2C bus where the airspeed sensor is connected. May not correspond to board's I2C bus number labels. Retry another bus and reboot if airspeed sensor fails to initialize.
| Value | Meaning |
|---|---|
| 0 | Bus0 |
| 1 | Bus1 |
| 2 | Bus2 |
| 3 | Bus3 |
Airspeed sensor ID, taking into account its type, bus and instance
calibrated ground pressure in Pascals
User provided ambient ground temperature in degrees Celsius. This is used to improve the calculation of the altitude the vehicle is at. This parameter is not persistent and will be reset to 0 every time the vehicle is rebooted. A value of 0 means use the internal measurement ambient temperature.
altitude offset in meters added to barometric altitude. This is used to allow for automatic adjustment of the base barometric altitude by a ground station equipped with a barometer. The value is added to the barometric altitude read by the aircraft. It is automatically reset to 0 when the barometer is calibrated on each reboot or when a preflight calibration is performed.
This selects which barometer will be the primary if multiple barometers are found
| Value | Meaning |
|---|---|
| 0 | FirstBaro |
| 1 | 2ndBaro |
| 2 | 3rdBaro |
This selects the bus number for looking for an I2C barometer. When set to -1 it will probe all external i2c buses based on the BARO_PROBE_EXT parameter.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 0 | Bus0 |
| 1 | Bus1 |
| 6 | Bus6 |
calibrated ground pressure in Pascals
calibrated ground pressure in Pascals
This sets the range around the average value that new samples must be within to be accepted. This can help reduce the impact of noise on sensors that are on long I2C cables. The value is a percentage from the average value. A value of zero disables this filter.
This sets which types of external i2c barometer to look for. It is a bitmask of barometer types. The I2C buses to probe is based on BARO_EXT_BUS. If BARO_EXT_BUS is -1 then it will probe all external buses, otherwise it will probe just the bus number given in BARO_EXT_BUS.
Barometer sensor ID, taking into account its type, bus and instance
Barometer2 sensor ID, taking into account its type, bus and instance
Barometer3 sensor ID, taking into account its type, bus and instance
User provided field elevation in meters. This is used to improve the calculation of the altitude the vehicle is at. This parameter is not persistent and will be reset to 0 every time the vehicle is rebooted. Changes to this parameter will only be used when disarmed. A value of 0 means the EKF origin height is used for takeoff height above sea level.
This is the maximum acceptable altitude discrepancy between GPS altitude and barometric presssure altitude calculated against a standard atmosphere for arming checks to pass. If you are getting an arming error due to this parameter then you may have a faulty or substituted barometer. A common issue is vendors replacing a MS5611 in a "Pixhawk" with a MS5607. If you have that issue then please see BARO_OPTIONS parameter to force the MS5611 to be treated as a MS5607. This check is disabled if the value is zero.
Barometer options
Thrust scaling in Pascals. This value scaled by the normalized thrust is subtracted from the barometer pressure. This is used to adjust linearly based on the thrust output for local pressure difference induced by the props.
This enables the use of wind coefficients for barometer compensation
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
This is the ratio of static pressure error to dynamic pressure generated by a positive wind relative velocity along the X body axis. If the baro height estimate rises during forwards flight, then this will be a negative number. Multirotors can use this feature only if using EKF3 and if the EK3_DRAG_BCOEF_X and EK3_DRAG_BCOEF_Y parameters have been tuned.
This is the ratio of static pressure error to dynamic pressure generated by a negative wind relative velocity along the X body axis. If the baro height estimate rises during backwards flight, then this will be a negative number. Multirotors can use this feature only if using EKF3 and if the EK3_DRAG_BCOEF_X and EK3_DRAG_BCOEF_Y parameters have been tuned.
This is the ratio of static pressure error to dynamic pressure generated by a positive wind relative velocity along the Y body axis. If the baro height estimate rises during sideways flight to the right, then this should be a negative number. Multirotors can use this feature only if using EKF3 and if the EK3_DRAG_BCOEF_X and EK3_DRAG_BCOEF_Y parameters have been tuned.
This is the ratio of static pressure error to dynamic pressure generated by a negative wind relative velocity along the Y body axis. If the baro height estimate rises during sideways flight to the left, then this should be a negative number. Multirotors can use this feature only if using EKF3 and if the EK3_DRAG_BCOEF_X and EK3_DRAG_BCOEF_Y parameters have been tuned.
This is the ratio of static pressure error to dynamic pressure generated by a positive wind relative velocity along the Z body axis. If the baro height estimate rises above truth height during climbing flight (or forward flight with a high forwards lean angle), then this should be a negative number. Multirotors can use this feature only if using EKF3 and if the EK3_DRAG_BCOEF_X and EK3_DRAG_BCOEF_Y parameters have been tuned.
This is the ratio of static pressure error to dynamic pressure generated by a negative wind relative velocity along the Z body axis. If the baro height estimate rises above truth height during descending flight (or forward flight with a high backwards lean angle, eg braking manoeuvre), then this should be a negative number. Multirotors can use this feature only if using EKF3 and if the EK3_DRAG_BCOEF_X and EK3_DRAG_BCOEF_Y parameters have been tuned.
This enables the use of wind coefficients for barometer compensation
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
This is the ratio of static pressure error to dynamic pressure generated by a positive wind relative velocity along the X body axis. If the baro height estimate rises during forwards flight, then this will be a negative number. Multirotors can use this feature only if using EKF3 and if the EK3_DRAG_BCOEF_X and EK3_DRAG_BCOEF_Y parameters have been tuned.
This is the ratio of static pressure error to dynamic pressure generated by a negative wind relative velocity along the X body axis. If the baro height estimate rises during backwards flight, then this will be a negative number. Multirotors can use this feature only if using EKF3 and if the EK3_DRAG_BCOEF_X and EK3_DRAG_BCOEF_Y parameters have been tuned.
This is the ratio of static pressure error to dynamic pressure generated by a positive wind relative velocity along the Y body axis. If the baro height estimate rises during sideways flight to the right, then this should be a negative number. Multirotors can use this feature only if using EKF3 and if the EK3_DRAG_BCOEF_X and EK3_DRAG_BCOEF_Y parameters have been tuned.
This is the ratio of static pressure error to dynamic pressure generated by a negative wind relative velocity along the Y body axis. If the baro height estimate rises during sideways flight to the left, then this should be a negative number. Multirotors can use this feature only if using EKF3 and if the EK3_DRAG_BCOEF_X and EK3_DRAG_BCOEF_Y parameters have been tuned.
This is the ratio of static pressure error to dynamic pressure generated by a positive wind relative velocity along the Z body axis. If the baro height estimate rises above truth height during climbing flight (or forward flight with a high forwards lean angle), then this should be a negative number. Multirotors can use this feature only if using EKF3 and if the EK3_DRAG_BCOEF_X and EK3_DRAG_BCOEF_Y parameters have been tuned.
This is the ratio of static pressure error to dynamic pressure generated by a negative wind relative velocity along the Z body axis. If the baro height estimate rises above truth height during descending flight (or forward flight with a high backwards lean angle, eg braking manoeuvre), then this should be a negative number. Multirotors can use this feature only if using EKF3 and if the EK3_DRAG_BCOEF_X and EK3_DRAG_BCOEF_Y parameters have been tuned.
This enables the use of wind coefficients for barometer compensation
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
This is the ratio of static pressure error to dynamic pressure generated by a positive wind relative velocity along the X body axis. If the baro height estimate rises during forwards flight, then this will be a negative number. Multirotors can use this feature only if using EKF3 and if the EK3_DRAG_BCOEF_X and EK3_DRAG_BCOEF_Y parameters have been tuned.
This is the ratio of static pressure error to dynamic pressure generated by a negative wind relative velocity along the X body axis. If the baro height estimate rises during backwards flight, then this will be a negative number. Multirotors can use this feature only if using EKF3 and if the EK3_DRAG_BCOEF_X and EK3_DRAG_BCOEF_Y parameters have been tuned.
This is the ratio of static pressure error to dynamic pressure generated by a positive wind relative velocity along the Y body axis. If the baro height estimate rises during sideways flight to the right, then this should be a negative number. Multirotors can use this feature only if using EKF3 and if the EK3_DRAG_BCOEF_X and EK3_DRAG_BCOEF_Y parameters have been tuned.
This is the ratio of static pressure error to dynamic pressure generated by a negative wind relative velocity along the Y body axis. If the baro height estimate rises during sideways flight to the left, then this should be a negative number. Multirotors can use this feature only if using EKF3 and if the EK3_DRAG_BCOEF_X and EK3_DRAG_BCOEF_Y parameters have been tuned.
This is the ratio of static pressure error to dynamic pressure generated by a positive wind relative velocity along the Z body axis. If the baro height estimate rises above truth height during climbing flight (or forward flight with a high forwards lean angle), then this should be a negative number. Multirotors can use this feature only if using EKF3 and if the EK3_DRAG_BCOEF_X and EK3_DRAG_BCOEF_Y parameters have been tuned.
This is the ratio of static pressure error to dynamic pressure generated by a negative wind relative velocity along the Z body axis. If the baro height estimate rises above truth height during descending flight (or forward flight with a high backwards lean angle, eg braking manoeuvre), then this should be a negative number. Multirotors can use this feature only if using EKF3 and if the EK3_DRAG_BCOEF_X and EK3_DRAG_BCOEF_Y parameters have been tuned.
Controls enabling monitoring of the battery's voltage and current
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 3 | Analog Voltage Only |
| 4 | Analog Voltage and Current |
| 5 | Solo |
| 6 | Bebop |
| 7 | SMBus-Generic |
| 8 | DroneCAN-BatteryInfo |
| 9 | ESC |
| 10 | Sum Of Selected Monitors |
| 11 | FuelFlow |
| 12 | FuelLevelPWM |
| 13 | SMBUS-SUI3 |
| 14 | SMBUS-SUI6 |
| 15 | NeoDesign |
| 16 | SMBus-Maxell |
| 17 | Generator-Elec |
| 18 | Generator-Fuel |
| 19 | Rotoye |
| 20 | MPPT |
| 21 | INA2XX |
| 22 | LTC2946 |
| 23 | Torqeedo |
| 24 | FuelLevelAnalog |
| 25 | Synthetic Current and Analog Voltage |
| 26 | INA239_SPI |
| 27 | EFI |
| 28 | AD7091R5 |
| 29 | Scripting |
| 30 | INA3221 |
Capacity of the battery in mAh when full
Battery serial number, automatically filled in for SMBus batteries, otherwise will be -1. With DroneCan it is the battery_id.
This is the timeout in seconds before a low voltage event will be triggered. For aircraft with low C batteries it may be necessary to raise this in order to cope with low voltage on long takeoffs. A value of zero disables low voltage errors.
Voltage type used for detection of low voltage event
| Value | Meaning |
|---|---|
| 0 | Raw Voltage |
| 1 | Sag Compensated Voltage |
Battery voltage that triggers a low battery failsafe. Set to 0 to disable. If the battery voltage drops below this voltage continuously for more then the period specified by the BATT2_LOW_TIMER parameter then the vehicle will perform the failsafe specified by the BATT2_FS_LOW_ACT parameter.
Battery capacity at which the low battery failsafe is triggered. Set to 0 to disable battery remaining failsafe. If the battery capacity drops below this level the vehicle will perform the failsafe specified by the BATT2_FS_LOW_ACT parameter.
Battery voltage that triggers a critical battery failsafe. Set to 0 to disable. If the battery voltage drops below this voltage continuously for more then the period specified by the BATT2_LOW_TIMER parameter then the vehicle will perform the failsafe specified by the BATT2_FS_CRT_ACT parameter.
Battery capacity at which the critical battery failsafe is triggered. Set to 0 to disable battery remaining failsafe. If the battery capacity drops below this level the vehicle will perform the failsafe specified by the BATT2_FS_CRT_ACT parameter.
What action the vehicle should perform if it hits a low battery failsafe
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Land |
What action the vehicle should perform if it hits a critical battery failsafe
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Land |
Battery voltage level which is required to arm the aircraft. Set to 0 to allow arming at any voltage.
Battery capacity remaining which is required to arm the aircraft. Set to 0 to allow arming at any capacity. Note that execept for smart batteries rebooting the vehicle will always reset the remaining capacity estimate, which can lead to this check not providing sufficent protection, it is recommended to always use this in conjunction with the BATT2_ARM_VOLT parameter.
This sets options to change the behaviour of the battery monitor
ESC Telemetry Index to write voltage, current, consumption and temperature data to. Use 0 to disable.
Sets the analog input pin that should be used for voltage monitoring.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
Sets the analog input pin that should be used for current monitoring.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 3 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 4 | CubeOrange_PM2/Navigator |
| 14 | Pixhawk2_PM2 |
| 15 | CubeOrange |
| 17 | Durandal |
| 101 | PX4-v1 |
Used to convert the voltage of the voltage sensing pin (BATT2_VOLT_PIN) to the actual battery's voltage (pin_voltage * VOLT_MULT). For the 3DR Power brick with a Pixhawk, this should be set to 10.1. For the Pixhawk with the 3DR 4in1 ESC this should be 12.02. For the PX using the PX4IO power supply this should be set to 1.
Number of amps that a 1V reading on the current sensor corresponds to. With a Pixhawk using the 3DR Power brick this should be set to 17. For the Pixhawk with the 3DR 4in1 ESC this should be 17. For Synthetic Current sensor monitors, this is the maximum, full throttle current draw.
Voltage offset at zero current on current sensor for Analog Sensors. For Synthetic Current sensor, this offset is the zero throttle system current and is added to the calculated throttle base current.
Voltage offset on voltage pin. This allows for an offset due to a diode. This voltage is subtracted before the scaling is applied.
Battery monitor I2C bus number
Battery monitor I2C address
0: sum of remaining battery monitors, If none 0 sum of specified monitors. Current will be summed and voltages averaged.
Multiplier applied to all current related reports to allow for adjustment if no UAVCAN param access or current splitting applications
The voltage seen on the analog pin when the fuel tank is empty. Note: For this type of battery monitor, the voltage seen by the analog pin is displayed as battery voltage on a GCS.
Voltage multiplier to determine what the full tank voltage reading is. This is calculated as 1 / (Voltage_Full - Voltage_Empty) Note: For this type of battery monitor, the voltage seen by the analog pin is displayed as battery voltage on a GCS.
Filter frequency in Hertz where a low pass filter is used. This is used to filter out tank slosh from the fuel level reading. A value of -1 disables the filter and unfiltered voltage is used to determine the fuel level. The suggested values at in the range of 0.2 Hz to 0.5 Hz.
Analog input pin that fuel level sensor is connected to.Analog Airspeed or RSSI ports can be used for Analog input( some autopilots provide others also). Values for some autopilots are given as examples. Search wiki for "Analog pins".
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
First order polynomial fit term
Second order polynomial fit term
Third order polynomial fit term
Offset polynomial fit term
Maximum voltage of battery. Provides scaling of current versus voltage
Battery monitor I2C bus number
Battery monitor I2C address. If this is zero then probe list of supported addresses
This controls the maximum current the INS2XX sensor will work with.
This sets the shunt resistor used in the device
If 0 all connected ESCs will be used. If non-zero, only those selected in will be used.
This controls the maximum current the INA239 sensor will work with.
This sets the shunt resistor used in the device
Battery monitor I2C bus number
Battery monitor I2C address. If this is zero then probe list of supported addresses
INA3221 channel to return data for
Sets the analog input pin that should be used for voltage monitoring on AD7091R5.
| Value | Meaning |
|---|---|
| -1 | Disabled |
Sets the analog input pin that should be used for Current monitoring on AD7091R5.
| Value | Meaning |
|---|---|
| -1 | Disabled |
Used to convert the voltage of the voltage sensing pin (BATT2_VOLT_PIN) to the actual battery's voltage (pin_voltage * VOLT_MULT).
Number of amps that a 1V reading on the current sensor corresponds to.
Voltage offset at zero current on current sensor
Voltage offset on voltage pin. This allows for an offset due to a diode. This voltage is subtracted before the scaling is applied
Controls enabling monitoring of the battery's voltage and current
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 3 | Analog Voltage Only |
| 4 | Analog Voltage and Current |
| 5 | Solo |
| 6 | Bebop |
| 7 | SMBus-Generic |
| 8 | DroneCAN-BatteryInfo |
| 9 | ESC |
| 10 | Sum Of Selected Monitors |
| 11 | FuelFlow |
| 12 | FuelLevelPWM |
| 13 | SMBUS-SUI3 |
| 14 | SMBUS-SUI6 |
| 15 | NeoDesign |
| 16 | SMBus-Maxell |
| 17 | Generator-Elec |
| 18 | Generator-Fuel |
| 19 | Rotoye |
| 20 | MPPT |
| 21 | INA2XX |
| 22 | LTC2946 |
| 23 | Torqeedo |
| 24 | FuelLevelAnalog |
| 25 | Synthetic Current and Analog Voltage |
| 26 | INA239_SPI |
| 27 | EFI |
| 28 | AD7091R5 |
| 29 | Scripting |
| 30 | INA3221 |
Capacity of the battery in mAh when full
Battery serial number, automatically filled in for SMBus batteries, otherwise will be -1. With DroneCan it is the battery_id.
This is the timeout in seconds before a low voltage event will be triggered. For aircraft with low C batteries it may be necessary to raise this in order to cope with low voltage on long takeoffs. A value of zero disables low voltage errors.
Voltage type used for detection of low voltage event
| Value | Meaning |
|---|---|
| 0 | Raw Voltage |
| 1 | Sag Compensated Voltage |
Battery voltage that triggers a low battery failsafe. Set to 0 to disable. If the battery voltage drops below this voltage continuously for more then the period specified by the BATT3_LOW_TIMER parameter then the vehicle will perform the failsafe specified by the BATT3_FS_LOW_ACT parameter.
Battery capacity at which the low battery failsafe is triggered. Set to 0 to disable battery remaining failsafe. If the battery capacity drops below this level the vehicle will perform the failsafe specified by the BATT3_FS_LOW_ACT parameter.
Battery voltage that triggers a critical battery failsafe. Set to 0 to disable. If the battery voltage drops below this voltage continuously for more then the period specified by the BATT3_LOW_TIMER parameter then the vehicle will perform the failsafe specified by the BATT3_FS_CRT_ACT parameter.
Battery capacity at which the critical battery failsafe is triggered. Set to 0 to disable battery remaining failsafe. If the battery capacity drops below this level the vehicle will perform the failsafe specified by the BATT3_FS_CRT_ACT parameter.
What action the vehicle should perform if it hits a low battery failsafe
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Land |
What action the vehicle should perform if it hits a critical battery failsafe
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Land |
Battery voltage level which is required to arm the aircraft. Set to 0 to allow arming at any voltage.
Battery capacity remaining which is required to arm the aircraft. Set to 0 to allow arming at any capacity. Note that execept for smart batteries rebooting the vehicle will always reset the remaining capacity estimate, which can lead to this check not providing sufficent protection, it is recommended to always use this in conjunction with the BATT3_ARM_VOLT parameter.
This sets options to change the behaviour of the battery monitor
ESC Telemetry Index to write voltage, current, consumption and temperature data to. Use 0 to disable.
Sets the analog input pin that should be used for voltage monitoring.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
Sets the analog input pin that should be used for current monitoring.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 3 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 4 | CubeOrange_PM2/Navigator |
| 14 | Pixhawk2_PM2 |
| 15 | CubeOrange |
| 17 | Durandal |
| 101 | PX4-v1 |
Used to convert the voltage of the voltage sensing pin (BATT3_VOLT_PIN) to the actual battery's voltage (pin_voltage * VOLT_MULT). For the 3DR Power brick with a Pixhawk, this should be set to 10.1. For the Pixhawk with the 3DR 4in1 ESC this should be 12.02. For the PX using the PX4IO power supply this should be set to 1.
Number of amps that a 1V reading on the current sensor corresponds to. With a Pixhawk using the 3DR Power brick this should be set to 17. For the Pixhawk with the 3DR 4in1 ESC this should be 17. For Synthetic Current sensor monitors, this is the maximum, full throttle current draw.
Voltage offset at zero current on current sensor for Analog Sensors. For Synthetic Current sensor, this offset is the zero throttle system current and is added to the calculated throttle base current.
Voltage offset on voltage pin. This allows for an offset due to a diode. This voltage is subtracted before the scaling is applied.
Battery monitor I2C bus number
Battery monitor I2C address
0: sum of remaining battery monitors, If none 0 sum of specified monitors. Current will be summed and voltages averaged.
Multiplier applied to all current related reports to allow for adjustment if no UAVCAN param access or current splitting applications
The voltage seen on the analog pin when the fuel tank is empty. Note: For this type of battery monitor, the voltage seen by the analog pin is displayed as battery voltage on a GCS.
Voltage multiplier to determine what the full tank voltage reading is. This is calculated as 1 / (Voltage_Full - Voltage_Empty) Note: For this type of battery monitor, the voltage seen by the analog pin is displayed as battery voltage on a GCS.
Filter frequency in Hertz where a low pass filter is used. This is used to filter out tank slosh from the fuel level reading. A value of -1 disables the filter and unfiltered voltage is used to determine the fuel level. The suggested values at in the range of 0.2 Hz to 0.5 Hz.
Analog input pin that fuel level sensor is connected to.Analog Airspeed or RSSI ports can be used for Analog input( some autopilots provide others also). Values for some autopilots are given as examples. Search wiki for "Analog pins".
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
First order polynomial fit term
Second order polynomial fit term
Third order polynomial fit term
Offset polynomial fit term
Maximum voltage of battery. Provides scaling of current versus voltage
Battery monitor I2C bus number
Battery monitor I2C address. If this is zero then probe list of supported addresses
This controls the maximum current the INS2XX sensor will work with.
This sets the shunt resistor used in the device
If 0 all connected ESCs will be used. If non-zero, only those selected in will be used.
This controls the maximum current the INA239 sensor will work with.
This sets the shunt resistor used in the device
Battery monitor I2C bus number
Battery monitor I2C address. If this is zero then probe list of supported addresses
INA3221 channel to return data for
Sets the analog input pin that should be used for voltage monitoring on AD7091R5.
| Value | Meaning |
|---|---|
| -1 | Disabled |
Sets the analog input pin that should be used for Current monitoring on AD7091R5.
| Value | Meaning |
|---|---|
| -1 | Disabled |
Used to convert the voltage of the voltage sensing pin (BATT3_VOLT_PIN) to the actual battery's voltage (pin_voltage * VOLT_MULT).
Number of amps that a 1V reading on the current sensor corresponds to.
Voltage offset at zero current on current sensor
Voltage offset on voltage pin. This allows for an offset due to a diode. This voltage is subtracted before the scaling is applied
Controls enabling monitoring of the battery's voltage and current
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 3 | Analog Voltage Only |
| 4 | Analog Voltage and Current |
| 5 | Solo |
| 6 | Bebop |
| 7 | SMBus-Generic |
| 8 | DroneCAN-BatteryInfo |
| 9 | ESC |
| 10 | Sum Of Selected Monitors |
| 11 | FuelFlow |
| 12 | FuelLevelPWM |
| 13 | SMBUS-SUI3 |
| 14 | SMBUS-SUI6 |
| 15 | NeoDesign |
| 16 | SMBus-Maxell |
| 17 | Generator-Elec |
| 18 | Generator-Fuel |
| 19 | Rotoye |
| 20 | MPPT |
| 21 | INA2XX |
| 22 | LTC2946 |
| 23 | Torqeedo |
| 24 | FuelLevelAnalog |
| 25 | Synthetic Current and Analog Voltage |
| 26 | INA239_SPI |
| 27 | EFI |
| 28 | AD7091R5 |
| 29 | Scripting |
| 30 | INA3221 |
Capacity of the battery in mAh when full
Battery serial number, automatically filled in for SMBus batteries, otherwise will be -1. With DroneCan it is the battery_id.
This is the timeout in seconds before a low voltage event will be triggered. For aircraft with low C batteries it may be necessary to raise this in order to cope with low voltage on long takeoffs. A value of zero disables low voltage errors.
Voltage type used for detection of low voltage event
| Value | Meaning |
|---|---|
| 0 | Raw Voltage |
| 1 | Sag Compensated Voltage |
Battery voltage that triggers a low battery failsafe. Set to 0 to disable. If the battery voltage drops below this voltage continuously for more then the period specified by the BATT4_LOW_TIMER parameter then the vehicle will perform the failsafe specified by the BATT4_FS_LOW_ACT parameter.
Battery capacity at which the low battery failsafe is triggered. Set to 0 to disable battery remaining failsafe. If the battery capacity drops below this level the vehicle will perform the failsafe specified by the BATT4_FS_LOW_ACT parameter.
Battery voltage that triggers a critical battery failsafe. Set to 0 to disable. If the battery voltage drops below this voltage continuously for more then the period specified by the BATT4_LOW_TIMER parameter then the vehicle will perform the failsafe specified by the BATT4_FS_CRT_ACT parameter.
Battery capacity at which the critical battery failsafe is triggered. Set to 0 to disable battery remaining failsafe. If the battery capacity drops below this level the vehicle will perform the failsafe specified by the BATT4_FS_CRT_ACT parameter.
What action the vehicle should perform if it hits a low battery failsafe
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Land |
What action the vehicle should perform if it hits a critical battery failsafe
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Land |
Battery voltage level which is required to arm the aircraft. Set to 0 to allow arming at any voltage.
Battery capacity remaining which is required to arm the aircraft. Set to 0 to allow arming at any capacity. Note that execept for smart batteries rebooting the vehicle will always reset the remaining capacity estimate, which can lead to this check not providing sufficent protection, it is recommended to always use this in conjunction with the BATT4_ARM_VOLT parameter.
This sets options to change the behaviour of the battery monitor
ESC Telemetry Index to write voltage, current, consumption and temperature data to. Use 0 to disable.
Sets the analog input pin that should be used for voltage monitoring.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
Sets the analog input pin that should be used for current monitoring.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 3 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 4 | CubeOrange_PM2/Navigator |
| 14 | Pixhawk2_PM2 |
| 15 | CubeOrange |
| 17 | Durandal |
| 101 | PX4-v1 |
Used to convert the voltage of the voltage sensing pin (BATT4_VOLT_PIN) to the actual battery's voltage (pin_voltage * VOLT_MULT). For the 3DR Power brick with a Pixhawk, this should be set to 10.1. For the Pixhawk with the 3DR 4in1 ESC this should be 12.02. For the PX using the PX4IO power supply this should be set to 1.
Number of amps that a 1V reading on the current sensor corresponds to. With a Pixhawk using the 3DR Power brick this should be set to 17. For the Pixhawk with the 3DR 4in1 ESC this should be 17. For Synthetic Current sensor monitors, this is the maximum, full throttle current draw.
Voltage offset at zero current on current sensor for Analog Sensors. For Synthetic Current sensor, this offset is the zero throttle system current and is added to the calculated throttle base current.
Voltage offset on voltage pin. This allows for an offset due to a diode. This voltage is subtracted before the scaling is applied.
Battery monitor I2C bus number
Battery monitor I2C address
0: sum of remaining battery monitors, If none 0 sum of specified monitors. Current will be summed and voltages averaged.
Multiplier applied to all current related reports to allow for adjustment if no UAVCAN param access or current splitting applications
The voltage seen on the analog pin when the fuel tank is empty. Note: For this type of battery monitor, the voltage seen by the analog pin is displayed as battery voltage on a GCS.
Voltage multiplier to determine what the full tank voltage reading is. This is calculated as 1 / (Voltage_Full - Voltage_Empty) Note: For this type of battery monitor, the voltage seen by the analog pin is displayed as battery voltage on a GCS.
Filter frequency in Hertz where a low pass filter is used. This is used to filter out tank slosh from the fuel level reading. A value of -1 disables the filter and unfiltered voltage is used to determine the fuel level. The suggested values at in the range of 0.2 Hz to 0.5 Hz.
Analog input pin that fuel level sensor is connected to.Analog Airspeed or RSSI ports can be used for Analog input( some autopilots provide others also). Values for some autopilots are given as examples. Search wiki for "Analog pins".
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
First order polynomial fit term
Second order polynomial fit term
Third order polynomial fit term
Offset polynomial fit term
Maximum voltage of battery. Provides scaling of current versus voltage
Battery monitor I2C bus number
Battery monitor I2C address. If this is zero then probe list of supported addresses
This controls the maximum current the INS2XX sensor will work with.
This sets the shunt resistor used in the device
If 0 all connected ESCs will be used. If non-zero, only those selected in will be used.
This controls the maximum current the INA239 sensor will work with.
This sets the shunt resistor used in the device
Battery monitor I2C bus number
Battery monitor I2C address. If this is zero then probe list of supported addresses
INA3221 channel to return data for
Sets the analog input pin that should be used for voltage monitoring on AD7091R5.
| Value | Meaning |
|---|---|
| -1 | Disabled |
Sets the analog input pin that should be used for Current monitoring on AD7091R5.
| Value | Meaning |
|---|---|
| -1 | Disabled |
Used to convert the voltage of the voltage sensing pin (BATT4_VOLT_PIN) to the actual battery's voltage (pin_voltage * VOLT_MULT).
Number of amps that a 1V reading on the current sensor corresponds to.
Voltage offset at zero current on current sensor
Voltage offset on voltage pin. This allows for an offset due to a diode. This voltage is subtracted before the scaling is applied
Controls enabling monitoring of the battery's voltage and current
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 3 | Analog Voltage Only |
| 4 | Analog Voltage and Current |
| 5 | Solo |
| 6 | Bebop |
| 7 | SMBus-Generic |
| 8 | DroneCAN-BatteryInfo |
| 9 | ESC |
| 10 | Sum Of Selected Monitors |
| 11 | FuelFlow |
| 12 | FuelLevelPWM |
| 13 | SMBUS-SUI3 |
| 14 | SMBUS-SUI6 |
| 15 | NeoDesign |
| 16 | SMBus-Maxell |
| 17 | Generator-Elec |
| 18 | Generator-Fuel |
| 19 | Rotoye |
| 20 | MPPT |
| 21 | INA2XX |
| 22 | LTC2946 |
| 23 | Torqeedo |
| 24 | FuelLevelAnalog |
| 25 | Synthetic Current and Analog Voltage |
| 26 | INA239_SPI |
| 27 | EFI |
| 28 | AD7091R5 |
| 29 | Scripting |
| 30 | INA3221 |
Capacity of the battery in mAh when full
Battery serial number, automatically filled in for SMBus batteries, otherwise will be -1. With DroneCan it is the battery_id.
This is the timeout in seconds before a low voltage event will be triggered. For aircraft with low C batteries it may be necessary to raise this in order to cope with low voltage on long takeoffs. A value of zero disables low voltage errors.
Voltage type used for detection of low voltage event
| Value | Meaning |
|---|---|
| 0 | Raw Voltage |
| 1 | Sag Compensated Voltage |
Battery voltage that triggers a low battery failsafe. Set to 0 to disable. If the battery voltage drops below this voltage continuously for more then the period specified by the BATT5_LOW_TIMER parameter then the vehicle will perform the failsafe specified by the BATT5_FS_LOW_ACT parameter.
Battery capacity at which the low battery failsafe is triggered. Set to 0 to disable battery remaining failsafe. If the battery capacity drops below this level the vehicle will perform the failsafe specified by the BATT5_FS_LOW_ACT parameter.
Battery voltage that triggers a critical battery failsafe. Set to 0 to disable. If the battery voltage drops below this voltage continuously for more then the period specified by the BATT5_LOW_TIMER parameter then the vehicle will perform the failsafe specified by the BATT5_FS_CRT_ACT parameter.
Battery capacity at which the critical battery failsafe is triggered. Set to 0 to disable battery remaining failsafe. If the battery capacity drops below this level the vehicle will perform the failsafe specified by the BATT5_FS_CRT_ACT parameter.
What action the vehicle should perform if it hits a low battery failsafe
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Land |
What action the vehicle should perform if it hits a critical battery failsafe
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Land |
Battery voltage level which is required to arm the aircraft. Set to 0 to allow arming at any voltage.
Battery capacity remaining which is required to arm the aircraft. Set to 0 to allow arming at any capacity. Note that execept for smart batteries rebooting the vehicle will always reset the remaining capacity estimate, which can lead to this check not providing sufficent protection, it is recommended to always use this in conjunction with the BATT5_ARM_VOLT parameter.
This sets options to change the behaviour of the battery monitor
ESC Telemetry Index to write voltage, current, consumption and temperature data to. Use 0 to disable.
Sets the analog input pin that should be used for voltage monitoring.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
Sets the analog input pin that should be used for current monitoring.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 3 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 4 | CubeOrange_PM2/Navigator |
| 14 | Pixhawk2_PM2 |
| 15 | CubeOrange |
| 17 | Durandal |
| 101 | PX4-v1 |
Used to convert the voltage of the voltage sensing pin (BATT5_VOLT_PIN) to the actual battery's voltage (pin_voltage * VOLT_MULT). For the 3DR Power brick with a Pixhawk, this should be set to 10.1. For the Pixhawk with the 3DR 4in1 ESC this should be 12.02. For the PX using the PX4IO power supply this should be set to 1.
Number of amps that a 1V reading on the current sensor corresponds to. With a Pixhawk using the 3DR Power brick this should be set to 17. For the Pixhawk with the 3DR 4in1 ESC this should be 17. For Synthetic Current sensor monitors, this is the maximum, full throttle current draw.
Voltage offset at zero current on current sensor for Analog Sensors. For Synthetic Current sensor, this offset is the zero throttle system current and is added to the calculated throttle base current.
Voltage offset on voltage pin. This allows for an offset due to a diode. This voltage is subtracted before the scaling is applied.
Battery monitor I2C bus number
Battery monitor I2C address
0: sum of remaining battery monitors, If none 0 sum of specified monitors. Current will be summed and voltages averaged.
Multiplier applied to all current related reports to allow for adjustment if no UAVCAN param access or current splitting applications
The voltage seen on the analog pin when the fuel tank is empty. Note: For this type of battery monitor, the voltage seen by the analog pin is displayed as battery voltage on a GCS.
Voltage multiplier to determine what the full tank voltage reading is. This is calculated as 1 / (Voltage_Full - Voltage_Empty) Note: For this type of battery monitor, the voltage seen by the analog pin is displayed as battery voltage on a GCS.
Filter frequency in Hertz where a low pass filter is used. This is used to filter out tank slosh from the fuel level reading. A value of -1 disables the filter and unfiltered voltage is used to determine the fuel level. The suggested values at in the range of 0.2 Hz to 0.5 Hz.
Analog input pin that fuel level sensor is connected to.Analog Airspeed or RSSI ports can be used for Analog input( some autopilots provide others also). Values for some autopilots are given as examples. Search wiki for "Analog pins".
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
First order polynomial fit term
Second order polynomial fit term
Third order polynomial fit term
Offset polynomial fit term
Maximum voltage of battery. Provides scaling of current versus voltage
Battery monitor I2C bus number
Battery monitor I2C address. If this is zero then probe list of supported addresses
This controls the maximum current the INS2XX sensor will work with.
This sets the shunt resistor used in the device
If 0 all connected ESCs will be used. If non-zero, only those selected in will be used.
This controls the maximum current the INA239 sensor will work with.
This sets the shunt resistor used in the device
Battery monitor I2C bus number
Battery monitor I2C address. If this is zero then probe list of supported addresses
INA3221 channel to return data for
Sets the analog input pin that should be used for voltage monitoring on AD7091R5.
| Value | Meaning |
|---|---|
| -1 | Disabled |
Sets the analog input pin that should be used for Current monitoring on AD7091R5.
| Value | Meaning |
|---|---|
| -1 | Disabled |
Used to convert the voltage of the voltage sensing pin (BATT5_VOLT_PIN) to the actual battery's voltage (pin_voltage * VOLT_MULT).
Number of amps that a 1V reading on the current sensor corresponds to.
Voltage offset at zero current on current sensor
Voltage offset on voltage pin. This allows for an offset due to a diode. This voltage is subtracted before the scaling is applied
Controls enabling monitoring of the battery's voltage and current
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 3 | Analog Voltage Only |
| 4 | Analog Voltage and Current |
| 5 | Solo |
| 6 | Bebop |
| 7 | SMBus-Generic |
| 8 | DroneCAN-BatteryInfo |
| 9 | ESC |
| 10 | Sum Of Selected Monitors |
| 11 | FuelFlow |
| 12 | FuelLevelPWM |
| 13 | SMBUS-SUI3 |
| 14 | SMBUS-SUI6 |
| 15 | NeoDesign |
| 16 | SMBus-Maxell |
| 17 | Generator-Elec |
| 18 | Generator-Fuel |
| 19 | Rotoye |
| 20 | MPPT |
| 21 | INA2XX |
| 22 | LTC2946 |
| 23 | Torqeedo |
| 24 | FuelLevelAnalog |
| 25 | Synthetic Current and Analog Voltage |
| 26 | INA239_SPI |
| 27 | EFI |
| 28 | AD7091R5 |
| 29 | Scripting |
| 30 | INA3221 |
Capacity of the battery in mAh when full
Battery serial number, automatically filled in for SMBus batteries, otherwise will be -1. With DroneCan it is the battery_id.
This is the timeout in seconds before a low voltage event will be triggered. For aircraft with low C batteries it may be necessary to raise this in order to cope with low voltage on long takeoffs. A value of zero disables low voltage errors.
Voltage type used for detection of low voltage event
| Value | Meaning |
|---|---|
| 0 | Raw Voltage |
| 1 | Sag Compensated Voltage |
Battery voltage that triggers a low battery failsafe. Set to 0 to disable. If the battery voltage drops below this voltage continuously for more then the period specified by the BATT6_LOW_TIMER parameter then the vehicle will perform the failsafe specified by the BATT6_FS_LOW_ACT parameter.
Battery capacity at which the low battery failsafe is triggered. Set to 0 to disable battery remaining failsafe. If the battery capacity drops below this level the vehicle will perform the failsafe specified by the BATT6_FS_LOW_ACT parameter.
Battery voltage that triggers a critical battery failsafe. Set to 0 to disable. If the battery voltage drops below this voltage continuously for more then the period specified by the BATT6_LOW_TIMER parameter then the vehicle will perform the failsafe specified by the BATT6_FS_CRT_ACT parameter.
Battery capacity at which the critical battery failsafe is triggered. Set to 0 to disable battery remaining failsafe. If the battery capacity drops below this level the vehicle will perform the failsafe specified by the BATT6_FS_CRT_ACT parameter.
What action the vehicle should perform if it hits a low battery failsafe
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Land |
What action the vehicle should perform if it hits a critical battery failsafe
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Land |
Battery voltage level which is required to arm the aircraft. Set to 0 to allow arming at any voltage.
Battery capacity remaining which is required to arm the aircraft. Set to 0 to allow arming at any capacity. Note that execept for smart batteries rebooting the vehicle will always reset the remaining capacity estimate, which can lead to this check not providing sufficent protection, it is recommended to always use this in conjunction with the BATT6_ARM_VOLT parameter.
This sets options to change the behaviour of the battery monitor
ESC Telemetry Index to write voltage, current, consumption and temperature data to. Use 0 to disable.
Sets the analog input pin that should be used for voltage monitoring.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
Sets the analog input pin that should be used for current monitoring.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 3 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 4 | CubeOrange_PM2/Navigator |
| 14 | Pixhawk2_PM2 |
| 15 | CubeOrange |
| 17 | Durandal |
| 101 | PX4-v1 |
Used to convert the voltage of the voltage sensing pin (BATT6_VOLT_PIN) to the actual battery's voltage (pin_voltage * VOLT_MULT). For the 3DR Power brick with a Pixhawk, this should be set to 10.1. For the Pixhawk with the 3DR 4in1 ESC this should be 12.02. For the PX using the PX4IO power supply this should be set to 1.
Number of amps that a 1V reading on the current sensor corresponds to. With a Pixhawk using the 3DR Power brick this should be set to 17. For the Pixhawk with the 3DR 4in1 ESC this should be 17. For Synthetic Current sensor monitors, this is the maximum, full throttle current draw.
Voltage offset at zero current on current sensor for Analog Sensors. For Synthetic Current sensor, this offset is the zero throttle system current and is added to the calculated throttle base current.
Voltage offset on voltage pin. This allows for an offset due to a diode. This voltage is subtracted before the scaling is applied.
Battery monitor I2C bus number
Battery monitor I2C address
0: sum of remaining battery monitors, If none 0 sum of specified monitors. Current will be summed and voltages averaged.
Multiplier applied to all current related reports to allow for adjustment if no UAVCAN param access or current splitting applications
The voltage seen on the analog pin when the fuel tank is empty. Note: For this type of battery monitor, the voltage seen by the analog pin is displayed as battery voltage on a GCS.
Voltage multiplier to determine what the full tank voltage reading is. This is calculated as 1 / (Voltage_Full - Voltage_Empty) Note: For this type of battery monitor, the voltage seen by the analog pin is displayed as battery voltage on a GCS.
Filter frequency in Hertz where a low pass filter is used. This is used to filter out tank slosh from the fuel level reading. A value of -1 disables the filter and unfiltered voltage is used to determine the fuel level. The suggested values at in the range of 0.2 Hz to 0.5 Hz.
Analog input pin that fuel level sensor is connected to.Analog Airspeed or RSSI ports can be used for Analog input( some autopilots provide others also). Values for some autopilots are given as examples. Search wiki for "Analog pins".
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
First order polynomial fit term
Second order polynomial fit term
Third order polynomial fit term
Offset polynomial fit term
Maximum voltage of battery. Provides scaling of current versus voltage
Battery monitor I2C bus number
Battery monitor I2C address. If this is zero then probe list of supported addresses
This controls the maximum current the INS2XX sensor will work with.
This sets the shunt resistor used in the device
If 0 all connected ESCs will be used. If non-zero, only those selected in will be used.
This controls the maximum current the INA239 sensor will work with.
This sets the shunt resistor used in the device
Battery monitor I2C bus number
Battery monitor I2C address. If this is zero then probe list of supported addresses
INA3221 channel to return data for
Sets the analog input pin that should be used for voltage monitoring on AD7091R5.
| Value | Meaning |
|---|---|
| -1 | Disabled |
Sets the analog input pin that should be used for Current monitoring on AD7091R5.
| Value | Meaning |
|---|---|
| -1 | Disabled |
Used to convert the voltage of the voltage sensing pin (BATT6_VOLT_PIN) to the actual battery's voltage (pin_voltage * VOLT_MULT).
Number of amps that a 1V reading on the current sensor corresponds to.
Voltage offset at zero current on current sensor
Voltage offset on voltage pin. This allows for an offset due to a diode. This voltage is subtracted before the scaling is applied
Controls enabling monitoring of the battery's voltage and current
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 3 | Analog Voltage Only |
| 4 | Analog Voltage and Current |
| 5 | Solo |
| 6 | Bebop |
| 7 | SMBus-Generic |
| 8 | DroneCAN-BatteryInfo |
| 9 | ESC |
| 10 | Sum Of Selected Monitors |
| 11 | FuelFlow |
| 12 | FuelLevelPWM |
| 13 | SMBUS-SUI3 |
| 14 | SMBUS-SUI6 |
| 15 | NeoDesign |
| 16 | SMBus-Maxell |
| 17 | Generator-Elec |
| 18 | Generator-Fuel |
| 19 | Rotoye |
| 20 | MPPT |
| 21 | INA2XX |
| 22 | LTC2946 |
| 23 | Torqeedo |
| 24 | FuelLevelAnalog |
| 25 | Synthetic Current and Analog Voltage |
| 26 | INA239_SPI |
| 27 | EFI |
| 28 | AD7091R5 |
| 29 | Scripting |
| 30 | INA3221 |
Capacity of the battery in mAh when full
Battery serial number, automatically filled in for SMBus batteries, otherwise will be -1. With DroneCan it is the battery_id.
This is the timeout in seconds before a low voltage event will be triggered. For aircraft with low C batteries it may be necessary to raise this in order to cope with low voltage on long takeoffs. A value of zero disables low voltage errors.
Voltage type used for detection of low voltage event
| Value | Meaning |
|---|---|
| 0 | Raw Voltage |
| 1 | Sag Compensated Voltage |
Battery voltage that triggers a low battery failsafe. Set to 0 to disable. If the battery voltage drops below this voltage continuously for more then the period specified by the BATT7_LOW_TIMER parameter then the vehicle will perform the failsafe specified by the BATT7_FS_LOW_ACT parameter.
Battery capacity at which the low battery failsafe is triggered. Set to 0 to disable battery remaining failsafe. If the battery capacity drops below this level the vehicle will perform the failsafe specified by the BATT7_FS_LOW_ACT parameter.
Battery voltage that triggers a critical battery failsafe. Set to 0 to disable. If the battery voltage drops below this voltage continuously for more then the period specified by the BATT7_LOW_TIMER parameter then the vehicle will perform the failsafe specified by the BATT7_FS_CRT_ACT parameter.
Battery capacity at which the critical battery failsafe is triggered. Set to 0 to disable battery remaining failsafe. If the battery capacity drops below this level the vehicle will perform the failsafe specified by the BATT7_FS_CRT_ACT parameter.
What action the vehicle should perform if it hits a low battery failsafe
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Land |
What action the vehicle should perform if it hits a critical battery failsafe
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Land |
Battery voltage level which is required to arm the aircraft. Set to 0 to allow arming at any voltage.
Battery capacity remaining which is required to arm the aircraft. Set to 0 to allow arming at any capacity. Note that execept for smart batteries rebooting the vehicle will always reset the remaining capacity estimate, which can lead to this check not providing sufficent protection, it is recommended to always use this in conjunction with the BATT7_ARM_VOLT parameter.
This sets options to change the behaviour of the battery monitor
ESC Telemetry Index to write voltage, current, consumption and temperature data to. Use 0 to disable.
Sets the analog input pin that should be used for voltage monitoring.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
Sets the analog input pin that should be used for current monitoring.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 3 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 4 | CubeOrange_PM2/Navigator |
| 14 | Pixhawk2_PM2 |
| 15 | CubeOrange |
| 17 | Durandal |
| 101 | PX4-v1 |
Used to convert the voltage of the voltage sensing pin (BATT7_VOLT_PIN) to the actual battery's voltage (pin_voltage * VOLT_MULT). For the 3DR Power brick with a Pixhawk, this should be set to 10.1. For the Pixhawk with the 3DR 4in1 ESC this should be 12.02. For the PX using the PX4IO power supply this should be set to 1.
Number of amps that a 1V reading on the current sensor corresponds to. With a Pixhawk using the 3DR Power brick this should be set to 17. For the Pixhawk with the 3DR 4in1 ESC this should be 17. For Synthetic Current sensor monitors, this is the maximum, full throttle current draw.
Voltage offset at zero current on current sensor for Analog Sensors. For Synthetic Current sensor, this offset is the zero throttle system current and is added to the calculated throttle base current.
Voltage offset on voltage pin. This allows for an offset due to a diode. This voltage is subtracted before the scaling is applied.
Battery monitor I2C bus number
Battery monitor I2C address
0: sum of remaining battery monitors, If none 0 sum of specified monitors. Current will be summed and voltages averaged.
Multiplier applied to all current related reports to allow for adjustment if no UAVCAN param access or current splitting applications
The voltage seen on the analog pin when the fuel tank is empty. Note: For this type of battery monitor, the voltage seen by the analog pin is displayed as battery voltage on a GCS.
Voltage multiplier to determine what the full tank voltage reading is. This is calculated as 1 / (Voltage_Full - Voltage_Empty) Note: For this type of battery monitor, the voltage seen by the analog pin is displayed as battery voltage on a GCS.
Filter frequency in Hertz where a low pass filter is used. This is used to filter out tank slosh from the fuel level reading. A value of -1 disables the filter and unfiltered voltage is used to determine the fuel level. The suggested values at in the range of 0.2 Hz to 0.5 Hz.
Analog input pin that fuel level sensor is connected to.Analog Airspeed or RSSI ports can be used for Analog input( some autopilots provide others also). Values for some autopilots are given as examples. Search wiki for "Analog pins".
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
First order polynomial fit term
Second order polynomial fit term
Third order polynomial fit term
Offset polynomial fit term
Maximum voltage of battery. Provides scaling of current versus voltage
Battery monitor I2C bus number
Battery monitor I2C address. If this is zero then probe list of supported addresses
This controls the maximum current the INS2XX sensor will work with.
This sets the shunt resistor used in the device
If 0 all connected ESCs will be used. If non-zero, only those selected in will be used.
This controls the maximum current the INA239 sensor will work with.
This sets the shunt resistor used in the device
Battery monitor I2C bus number
Battery monitor I2C address. If this is zero then probe list of supported addresses
INA3221 channel to return data for
Sets the analog input pin that should be used for voltage monitoring on AD7091R5.
| Value | Meaning |
|---|---|
| -1 | Disabled |
Sets the analog input pin that should be used for Current monitoring on AD7091R5.
| Value | Meaning |
|---|---|
| -1 | Disabled |
Used to convert the voltage of the voltage sensing pin (BATT7_VOLT_PIN) to the actual battery's voltage (pin_voltage * VOLT_MULT).
Number of amps that a 1V reading on the current sensor corresponds to.
Voltage offset at zero current on current sensor
Voltage offset on voltage pin. This allows for an offset due to a diode. This voltage is subtracted before the scaling is applied
Controls enabling monitoring of the battery's voltage and current
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 3 | Analog Voltage Only |
| 4 | Analog Voltage and Current |
| 5 | Solo |
| 6 | Bebop |
| 7 | SMBus-Generic |
| 8 | DroneCAN-BatteryInfo |
| 9 | ESC |
| 10 | Sum Of Selected Monitors |
| 11 | FuelFlow |
| 12 | FuelLevelPWM |
| 13 | SMBUS-SUI3 |
| 14 | SMBUS-SUI6 |
| 15 | NeoDesign |
| 16 | SMBus-Maxell |
| 17 | Generator-Elec |
| 18 | Generator-Fuel |
| 19 | Rotoye |
| 20 | MPPT |
| 21 | INA2XX |
| 22 | LTC2946 |
| 23 | Torqeedo |
| 24 | FuelLevelAnalog |
| 25 | Synthetic Current and Analog Voltage |
| 26 | INA239_SPI |
| 27 | EFI |
| 28 | AD7091R5 |
| 29 | Scripting |
| 30 | INA3221 |
Capacity of the battery in mAh when full
Battery serial number, automatically filled in for SMBus batteries, otherwise will be -1. With DroneCan it is the battery_id.
This is the timeout in seconds before a low voltage event will be triggered. For aircraft with low C batteries it may be necessary to raise this in order to cope with low voltage on long takeoffs. A value of zero disables low voltage errors.
Voltage type used for detection of low voltage event
| Value | Meaning |
|---|---|
| 0 | Raw Voltage |
| 1 | Sag Compensated Voltage |
Battery voltage that triggers a low battery failsafe. Set to 0 to disable. If the battery voltage drops below this voltage continuously for more then the period specified by the BATT8_LOW_TIMER parameter then the vehicle will perform the failsafe specified by the BATT8_FS_LOW_ACT parameter.
Battery capacity at which the low battery failsafe is triggered. Set to 0 to disable battery remaining failsafe. If the battery capacity drops below this level the vehicle will perform the failsafe specified by the BATT8_FS_LOW_ACT parameter.
Battery voltage that triggers a critical battery failsafe. Set to 0 to disable. If the battery voltage drops below this voltage continuously for more then the period specified by the BATT8_LOW_TIMER parameter then the vehicle will perform the failsafe specified by the BATT8_FS_CRT_ACT parameter.
Battery capacity at which the critical battery failsafe is triggered. Set to 0 to disable battery remaining failsafe. If the battery capacity drops below this level the vehicle will perform the failsafe specified by the BATT8_FS_CRT_ACT parameter.
What action the vehicle should perform if it hits a low battery failsafe
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Land |
What action the vehicle should perform if it hits a critical battery failsafe
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Land |
Battery voltage level which is required to arm the aircraft. Set to 0 to allow arming at any voltage.
Battery capacity remaining which is required to arm the aircraft. Set to 0 to allow arming at any capacity. Note that execept for smart batteries rebooting the vehicle will always reset the remaining capacity estimate, which can lead to this check not providing sufficent protection, it is recommended to always use this in conjunction with the BATT8_ARM_VOLT parameter.
This sets options to change the behaviour of the battery monitor
ESC Telemetry Index to write voltage, current, consumption and temperature data to. Use 0 to disable.
Sets the analog input pin that should be used for voltage monitoring.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
Sets the analog input pin that should be used for current monitoring.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 3 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 4 | CubeOrange_PM2/Navigator |
| 14 | Pixhawk2_PM2 |
| 15 | CubeOrange |
| 17 | Durandal |
| 101 | PX4-v1 |
Used to convert the voltage of the voltage sensing pin (BATT8_VOLT_PIN) to the actual battery's voltage (pin_voltage * VOLT_MULT). For the 3DR Power brick with a Pixhawk, this should be set to 10.1. For the Pixhawk with the 3DR 4in1 ESC this should be 12.02. For the PX using the PX4IO power supply this should be set to 1.
Number of amps that a 1V reading on the current sensor corresponds to. With a Pixhawk using the 3DR Power brick this should be set to 17. For the Pixhawk with the 3DR 4in1 ESC this should be 17. For Synthetic Current sensor monitors, this is the maximum, full throttle current draw.
Voltage offset at zero current on current sensor for Analog Sensors. For Synthetic Current sensor, this offset is the zero throttle system current and is added to the calculated throttle base current.
Voltage offset on voltage pin. This allows for an offset due to a diode. This voltage is subtracted before the scaling is applied.
Battery monitor I2C bus number
Battery monitor I2C address
0: sum of remaining battery monitors, If none 0 sum of specified monitors. Current will be summed and voltages averaged.
Multiplier applied to all current related reports to allow for adjustment if no UAVCAN param access or current splitting applications
The voltage seen on the analog pin when the fuel tank is empty. Note: For this type of battery monitor, the voltage seen by the analog pin is displayed as battery voltage on a GCS.
Voltage multiplier to determine what the full tank voltage reading is. This is calculated as 1 / (Voltage_Full - Voltage_Empty) Note: For this type of battery monitor, the voltage seen by the analog pin is displayed as battery voltage on a GCS.
Filter frequency in Hertz where a low pass filter is used. This is used to filter out tank slosh from the fuel level reading. A value of -1 disables the filter and unfiltered voltage is used to determine the fuel level. The suggested values at in the range of 0.2 Hz to 0.5 Hz.
Analog input pin that fuel level sensor is connected to.Analog Airspeed or RSSI ports can be used for Analog input( some autopilots provide others also). Values for some autopilots are given as examples. Search wiki for "Analog pins".
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
First order polynomial fit term
Second order polynomial fit term
Third order polynomial fit term
Offset polynomial fit term
Maximum voltage of battery. Provides scaling of current versus voltage
Battery monitor I2C bus number
Battery monitor I2C address. If this is zero then probe list of supported addresses
This controls the maximum current the INS2XX sensor will work with.
This sets the shunt resistor used in the device
If 0 all connected ESCs will be used. If non-zero, only those selected in will be used.
This controls the maximum current the INA239 sensor will work with.
This sets the shunt resistor used in the device
Battery monitor I2C bus number
Battery monitor I2C address. If this is zero then probe list of supported addresses
INA3221 channel to return data for
Sets the analog input pin that should be used for voltage monitoring on AD7091R5.
| Value | Meaning |
|---|---|
| -1 | Disabled |
Sets the analog input pin that should be used for Current monitoring on AD7091R5.
| Value | Meaning |
|---|---|
| -1 | Disabled |
Used to convert the voltage of the voltage sensing pin (BATT8_VOLT_PIN) to the actual battery's voltage (pin_voltage * VOLT_MULT).
Number of amps that a 1V reading on the current sensor corresponds to.
Voltage offset at zero current on current sensor
Voltage offset on voltage pin. This allows for an offset due to a diode. This voltage is subtracted before the scaling is applied
Controls enabling monitoring of the battery's voltage and current
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 3 | Analog Voltage Only |
| 4 | Analog Voltage and Current |
| 5 | Solo |
| 6 | Bebop |
| 7 | SMBus-Generic |
| 8 | DroneCAN-BatteryInfo |
| 9 | ESC |
| 10 | Sum Of Selected Monitors |
| 11 | FuelFlow |
| 12 | FuelLevelPWM |
| 13 | SMBUS-SUI3 |
| 14 | SMBUS-SUI6 |
| 15 | NeoDesign |
| 16 | SMBus-Maxell |
| 17 | Generator-Elec |
| 18 | Generator-Fuel |
| 19 | Rotoye |
| 20 | MPPT |
| 21 | INA2XX |
| 22 | LTC2946 |
| 23 | Torqeedo |
| 24 | FuelLevelAnalog |
| 25 | Synthetic Current and Analog Voltage |
| 26 | INA239_SPI |
| 27 | EFI |
| 28 | AD7091R5 |
| 29 | Scripting |
| 30 | INA3221 |
Capacity of the battery in mAh when full
Battery serial number, automatically filled in for SMBus batteries, otherwise will be -1. With DroneCan it is the battery_id.
This is the timeout in seconds before a low voltage event will be triggered. For aircraft with low C batteries it may be necessary to raise this in order to cope with low voltage on long takeoffs. A value of zero disables low voltage errors.
Voltage type used for detection of low voltage event
| Value | Meaning |
|---|---|
| 0 | Raw Voltage |
| 1 | Sag Compensated Voltage |
Battery voltage that triggers a low battery failsafe. Set to 0 to disable. If the battery voltage drops below this voltage continuously for more then the period specified by the BATT9_LOW_TIMER parameter then the vehicle will perform the failsafe specified by the BATT9_FS_LOW_ACT parameter.
Battery capacity at which the low battery failsafe is triggered. Set to 0 to disable battery remaining failsafe. If the battery capacity drops below this level the vehicle will perform the failsafe specified by the BATT9_FS_LOW_ACT parameter.
Battery voltage that triggers a critical battery failsafe. Set to 0 to disable. If the battery voltage drops below this voltage continuously for more then the period specified by the BATT9_LOW_TIMER parameter then the vehicle will perform the failsafe specified by the BATT9_FS_CRT_ACT parameter.
Battery capacity at which the critical battery failsafe is triggered. Set to 0 to disable battery remaining failsafe. If the battery capacity drops below this level the vehicle will perform the failsafe specified by the BATT9_FS_CRT_ACT parameter.
What action the vehicle should perform if it hits a low battery failsafe
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Land |
What action the vehicle should perform if it hits a critical battery failsafe
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Land |
Battery voltage level which is required to arm the aircraft. Set to 0 to allow arming at any voltage.
Battery capacity remaining which is required to arm the aircraft. Set to 0 to allow arming at any capacity. Note that execept for smart batteries rebooting the vehicle will always reset the remaining capacity estimate, which can lead to this check not providing sufficent protection, it is recommended to always use this in conjunction with the BATT9_ARM_VOLT parameter.
This sets options to change the behaviour of the battery monitor
ESC Telemetry Index to write voltage, current, consumption and temperature data to. Use 0 to disable.
Sets the analog input pin that should be used for voltage monitoring.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
Sets the analog input pin that should be used for current monitoring.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 3 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 4 | CubeOrange_PM2/Navigator |
| 14 | Pixhawk2_PM2 |
| 15 | CubeOrange |
| 17 | Durandal |
| 101 | PX4-v1 |
Used to convert the voltage of the voltage sensing pin (BATT9_VOLT_PIN) to the actual battery's voltage (pin_voltage * VOLT_MULT). For the 3DR Power brick with a Pixhawk, this should be set to 10.1. For the Pixhawk with the 3DR 4in1 ESC this should be 12.02. For the PX using the PX4IO power supply this should be set to 1.
Number of amps that a 1V reading on the current sensor corresponds to. With a Pixhawk using the 3DR Power brick this should be set to 17. For the Pixhawk with the 3DR 4in1 ESC this should be 17. For Synthetic Current sensor monitors, this is the maximum, full throttle current draw.
Voltage offset at zero current on current sensor for Analog Sensors. For Synthetic Current sensor, this offset is the zero throttle system current and is added to the calculated throttle base current.
Voltage offset on voltage pin. This allows for an offset due to a diode. This voltage is subtracted before the scaling is applied.
Battery monitor I2C bus number
Battery monitor I2C address
0: sum of remaining battery monitors, If none 0 sum of specified monitors. Current will be summed and voltages averaged.
Multiplier applied to all current related reports to allow for adjustment if no UAVCAN param access or current splitting applications
The voltage seen on the analog pin when the fuel tank is empty. Note: For this type of battery monitor, the voltage seen by the analog pin is displayed as battery voltage on a GCS.
Voltage multiplier to determine what the full tank voltage reading is. This is calculated as 1 / (Voltage_Full - Voltage_Empty) Note: For this type of battery monitor, the voltage seen by the analog pin is displayed as battery voltage on a GCS.
Filter frequency in Hertz where a low pass filter is used. This is used to filter out tank slosh from the fuel level reading. A value of -1 disables the filter and unfiltered voltage is used to determine the fuel level. The suggested values at in the range of 0.2 Hz to 0.5 Hz.
Analog input pin that fuel level sensor is connected to.Analog Airspeed or RSSI ports can be used for Analog input( some autopilots provide others also). Values for some autopilots are given as examples. Search wiki for "Analog pins".
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
First order polynomial fit term
Second order polynomial fit term
Third order polynomial fit term
Offset polynomial fit term
Maximum voltage of battery. Provides scaling of current versus voltage
Battery monitor I2C bus number
Battery monitor I2C address. If this is zero then probe list of supported addresses
This controls the maximum current the INS2XX sensor will work with.
This sets the shunt resistor used in the device
If 0 all connected ESCs will be used. If non-zero, only those selected in will be used.
This controls the maximum current the INA239 sensor will work with.
This sets the shunt resistor used in the device
Battery monitor I2C bus number
Battery monitor I2C address. If this is zero then probe list of supported addresses
INA3221 channel to return data for
Sets the analog input pin that should be used for voltage monitoring on AD7091R5.
| Value | Meaning |
|---|---|
| -1 | Disabled |
Sets the analog input pin that should be used for Current monitoring on AD7091R5.
| Value | Meaning |
|---|---|
| -1 | Disabled |
Used to convert the voltage of the voltage sensing pin (BATT9_VOLT_PIN) to the actual battery's voltage (pin_voltage * VOLT_MULT).
Number of amps that a 1V reading on the current sensor corresponds to.
Voltage offset at zero current on current sensor
Voltage offset on voltage pin. This allows for an offset due to a diode. This voltage is subtracted before the scaling is applied
Controls enabling monitoring of the battery's voltage and current
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 3 | Analog Voltage Only |
| 4 | Analog Voltage and Current |
| 5 | Solo |
| 6 | Bebop |
| 7 | SMBus-Generic |
| 8 | DroneCAN-BatteryInfo |
| 9 | ESC |
| 10 | Sum Of Selected Monitors |
| 11 | FuelFlow |
| 12 | FuelLevelPWM |
| 13 | SMBUS-SUI3 |
| 14 | SMBUS-SUI6 |
| 15 | NeoDesign |
| 16 | SMBus-Maxell |
| 17 | Generator-Elec |
| 18 | Generator-Fuel |
| 19 | Rotoye |
| 20 | MPPT |
| 21 | INA2XX |
| 22 | LTC2946 |
| 23 | Torqeedo |
| 24 | FuelLevelAnalog |
| 25 | Synthetic Current and Analog Voltage |
| 26 | INA239_SPI |
| 27 | EFI |
| 28 | AD7091R5 |
| 29 | Scripting |
| 30 | INA3221 |
Capacity of the battery in mAh when full
Battery serial number, automatically filled in for SMBus batteries, otherwise will be -1. With DroneCan it is the battery_id.
This is the timeout in seconds before a low voltage event will be triggered. For aircraft with low C batteries it may be necessary to raise this in order to cope with low voltage on long takeoffs. A value of zero disables low voltage errors.
Voltage type used for detection of low voltage event
| Value | Meaning |
|---|---|
| 0 | Raw Voltage |
| 1 | Sag Compensated Voltage |
Battery voltage that triggers a low battery failsafe. Set to 0 to disable. If the battery voltage drops below this voltage continuously for more then the period specified by the BATTA_LOW_TIMER parameter then the vehicle will perform the failsafe specified by the BATTA_FS_LOW_ACT parameter.
Battery capacity at which the low battery failsafe is triggered. Set to 0 to disable battery remaining failsafe. If the battery capacity drops below this level the vehicle will perform the failsafe specified by the BATTA_FS_LOW_ACT parameter.
Battery voltage that triggers a critical battery failsafe. Set to 0 to disable. If the battery voltage drops below this voltage continuously for more then the period specified by the BATTA_LOW_TIMER parameter then the vehicle will perform the failsafe specified by the BATTA_FS_CRT_ACT parameter.
Battery capacity at which the critical battery failsafe is triggered. Set to 0 to disable battery remaining failsafe. If the battery capacity drops below this level the vehicle will perform the failsafe specified by the BATTA_FS_CRT_ACT parameter.
What action the vehicle should perform if it hits a low battery failsafe
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Land |
What action the vehicle should perform if it hits a critical battery failsafe
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Land |
Battery voltage level which is required to arm the aircraft. Set to 0 to allow arming at any voltage.
Battery capacity remaining which is required to arm the aircraft. Set to 0 to allow arming at any capacity. Note that execept for smart batteries rebooting the vehicle will always reset the remaining capacity estimate, which can lead to this check not providing sufficent protection, it is recommended to always use this in conjunction with the BATTA_ARM_VOLT parameter.
This sets options to change the behaviour of the battery monitor
ESC Telemetry Index to write voltage, current, consumption and temperature data to. Use 0 to disable.
Sets the analog input pin that should be used for voltage monitoring.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
Sets the analog input pin that should be used for current monitoring.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 3 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 4 | CubeOrange_PM2/Navigator |
| 14 | Pixhawk2_PM2 |
| 15 | CubeOrange |
| 17 | Durandal |
| 101 | PX4-v1 |
Used to convert the voltage of the voltage sensing pin (BATTA_VOLT_PIN) to the actual battery's voltage (pin_voltage * VOLT_MULT). For the 3DR Power brick with a Pixhawk, this should be set to 10.1. For the Pixhawk with the 3DR 4in1 ESC this should be 12.02. For the PX using the PX4IO power supply this should be set to 1.
Number of amps that a 1V reading on the current sensor corresponds to. With a Pixhawk using the 3DR Power brick this should be set to 17. For the Pixhawk with the 3DR 4in1 ESC this should be 17. For Synthetic Current sensor monitors, this is the maximum, full throttle current draw.
Voltage offset at zero current on current sensor for Analog Sensors. For Synthetic Current sensor, this offset is the zero throttle system current and is added to the calculated throttle base current.
Voltage offset on voltage pin. This allows for an offset due to a diode. This voltage is subtracted before the scaling is applied.
Battery monitor I2C bus number
Battery monitor I2C address
0: sum of remaining battery monitors, If none 0 sum of specified monitors. Current will be summed and voltages averaged.
Multiplier applied to all current related reports to allow for adjustment if no UAVCAN param access or current splitting applications
The voltage seen on the analog pin when the fuel tank is empty. Note: For this type of battery monitor, the voltage seen by the analog pin is displayed as battery voltage on a GCS.
Voltage multiplier to determine what the full tank voltage reading is. This is calculated as 1 / (Voltage_Full - Voltage_Empty) Note: For this type of battery monitor, the voltage seen by the analog pin is displayed as battery voltage on a GCS.
Filter frequency in Hertz where a low pass filter is used. This is used to filter out tank slosh from the fuel level reading. A value of -1 disables the filter and unfiltered voltage is used to determine the fuel level. The suggested values at in the range of 0.2 Hz to 0.5 Hz.
Analog input pin that fuel level sensor is connected to.Analog Airspeed or RSSI ports can be used for Analog input( some autopilots provide others also). Values for some autopilots are given as examples. Search wiki for "Analog pins".
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
First order polynomial fit term
Second order polynomial fit term
Third order polynomial fit term
Offset polynomial fit term
Maximum voltage of battery. Provides scaling of current versus voltage
Battery monitor I2C bus number
Battery monitor I2C address. If this is zero then probe list of supported addresses
This controls the maximum current the INS2XX sensor will work with.
This sets the shunt resistor used in the device
If 0 all connected ESCs will be used. If non-zero, only those selected in will be used.
This controls the maximum current the INA239 sensor will work with.
This sets the shunt resistor used in the device
Battery monitor I2C bus number
Battery monitor I2C address. If this is zero then probe list of supported addresses
INA3221 channel to return data for
Sets the analog input pin that should be used for voltage monitoring on AD7091R5.
| Value | Meaning |
|---|---|
| -1 | Disabled |
Sets the analog input pin that should be used for Current monitoring on AD7091R5.
| Value | Meaning |
|---|---|
| -1 | Disabled |
Used to convert the voltage of the voltage sensing pin (BATTA_VOLT_PIN) to the actual battery's voltage (pin_voltage * VOLT_MULT).
Number of amps that a 1V reading on the current sensor corresponds to.
Voltage offset at zero current on current sensor
Voltage offset on voltage pin. This allows for an offset due to a diode. This voltage is subtracted before the scaling is applied
Controls enabling monitoring of the battery's voltage and current
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 3 | Analog Voltage Only |
| 4 | Analog Voltage and Current |
| 5 | Solo |
| 6 | Bebop |
| 7 | SMBus-Generic |
| 8 | DroneCAN-BatteryInfo |
| 9 | ESC |
| 10 | Sum Of Selected Monitors |
| 11 | FuelFlow |
| 12 | FuelLevelPWM |
| 13 | SMBUS-SUI3 |
| 14 | SMBUS-SUI6 |
| 15 | NeoDesign |
| 16 | SMBus-Maxell |
| 17 | Generator-Elec |
| 18 | Generator-Fuel |
| 19 | Rotoye |
| 20 | MPPT |
| 21 | INA2XX |
| 22 | LTC2946 |
| 23 | Torqeedo |
| 24 | FuelLevelAnalog |
| 25 | Synthetic Current and Analog Voltage |
| 26 | INA239_SPI |
| 27 | EFI |
| 28 | AD7091R5 |
| 29 | Scripting |
| 30 | INA3221 |
Capacity of the battery in mAh when full
Battery serial number, automatically filled in for SMBus batteries, otherwise will be -1. With DroneCan it is the battery_id.
This is the timeout in seconds before a low voltage event will be triggered. For aircraft with low C batteries it may be necessary to raise this in order to cope with low voltage on long takeoffs. A value of zero disables low voltage errors.
Voltage type used for detection of low voltage event
| Value | Meaning |
|---|---|
| 0 | Raw Voltage |
| 1 | Sag Compensated Voltage |
Battery voltage that triggers a low battery failsafe. Set to 0 to disable. If the battery voltage drops below this voltage continuously for more then the period specified by the BATTB_LOW_TIMER parameter then the vehicle will perform the failsafe specified by the BATTB_FS_LOW_ACT parameter.
Battery capacity at which the low battery failsafe is triggered. Set to 0 to disable battery remaining failsafe. If the battery capacity drops below this level the vehicle will perform the failsafe specified by the BATTB_FS_LOW_ACT parameter.
Battery voltage that triggers a critical battery failsafe. Set to 0 to disable. If the battery voltage drops below this voltage continuously for more then the period specified by the BATTB_LOW_TIMER parameter then the vehicle will perform the failsafe specified by the BATTB_FS_CRT_ACT parameter.
Battery capacity at which the critical battery failsafe is triggered. Set to 0 to disable battery remaining failsafe. If the battery capacity drops below this level the vehicle will perform the failsafe specified by the BATTB_FS_CRT_ACT parameter.
What action the vehicle should perform if it hits a low battery failsafe
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Land |
What action the vehicle should perform if it hits a critical battery failsafe
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Land |
Battery voltage level which is required to arm the aircraft. Set to 0 to allow arming at any voltage.
Battery capacity remaining which is required to arm the aircraft. Set to 0 to allow arming at any capacity. Note that execept for smart batteries rebooting the vehicle will always reset the remaining capacity estimate, which can lead to this check not providing sufficent protection, it is recommended to always use this in conjunction with the BATTB_ARM_VOLT parameter.
This sets options to change the behaviour of the battery monitor
ESC Telemetry Index to write voltage, current, consumption and temperature data to. Use 0 to disable.
Sets the analog input pin that should be used for voltage monitoring.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
Sets the analog input pin that should be used for current monitoring.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 3 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 4 | CubeOrange_PM2/Navigator |
| 14 | Pixhawk2_PM2 |
| 15 | CubeOrange |
| 17 | Durandal |
| 101 | PX4-v1 |
Used to convert the voltage of the voltage sensing pin (BATTB_VOLT_PIN) to the actual battery's voltage (pin_voltage * VOLT_MULT). For the 3DR Power brick with a Pixhawk, this should be set to 10.1. For the Pixhawk with the 3DR 4in1 ESC this should be 12.02. For the PX using the PX4IO power supply this should be set to 1.
Number of amps that a 1V reading on the current sensor corresponds to. With a Pixhawk using the 3DR Power brick this should be set to 17. For the Pixhawk with the 3DR 4in1 ESC this should be 17. For Synthetic Current sensor monitors, this is the maximum, full throttle current draw.
Voltage offset at zero current on current sensor for Analog Sensors. For Synthetic Current sensor, this offset is the zero throttle system current and is added to the calculated throttle base current.
Voltage offset on voltage pin. This allows for an offset due to a diode. This voltage is subtracted before the scaling is applied.
Battery monitor I2C bus number
Battery monitor I2C address
0: sum of remaining battery monitors, If none 0 sum of specified monitors. Current will be summed and voltages averaged.
Multiplier applied to all current related reports to allow for adjustment if no UAVCAN param access or current splitting applications
The voltage seen on the analog pin when the fuel tank is empty. Note: For this type of battery monitor, the voltage seen by the analog pin is displayed as battery voltage on a GCS.
Voltage multiplier to determine what the full tank voltage reading is. This is calculated as 1 / (Voltage_Full - Voltage_Empty) Note: For this type of battery monitor, the voltage seen by the analog pin is displayed as battery voltage on a GCS.
Filter frequency in Hertz where a low pass filter is used. This is used to filter out tank slosh from the fuel level reading. A value of -1 disables the filter and unfiltered voltage is used to determine the fuel level. The suggested values at in the range of 0.2 Hz to 0.5 Hz.
Analog input pin that fuel level sensor is connected to.Analog Airspeed or RSSI ports can be used for Analog input( some autopilots provide others also). Values for some autopilots are given as examples. Search wiki for "Analog pins".
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
First order polynomial fit term
Second order polynomial fit term
Third order polynomial fit term
Offset polynomial fit term
Maximum voltage of battery. Provides scaling of current versus voltage
Battery monitor I2C bus number
Battery monitor I2C address. If this is zero then probe list of supported addresses
This controls the maximum current the INS2XX sensor will work with.
This sets the shunt resistor used in the device
If 0 all connected ESCs will be used. If non-zero, only those selected in will be used.
This controls the maximum current the INA239 sensor will work with.
This sets the shunt resistor used in the device
Battery monitor I2C bus number
Battery monitor I2C address. If this is zero then probe list of supported addresses
INA3221 channel to return data for
Sets the analog input pin that should be used for voltage monitoring on AD7091R5.
| Value | Meaning |
|---|---|
| -1 | Disabled |
Sets the analog input pin that should be used for Current monitoring on AD7091R5.
| Value | Meaning |
|---|---|
| -1 | Disabled |
Used to convert the voltage of the voltage sensing pin (BATTB_VOLT_PIN) to the actual battery's voltage (pin_voltage * VOLT_MULT).
Number of amps that a 1V reading on the current sensor corresponds to.
Voltage offset at zero current on current sensor
Voltage offset on voltage pin. This allows for an offset due to a diode. This voltage is subtracted before the scaling is applied
Controls enabling monitoring of the battery's voltage and current
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 3 | Analog Voltage Only |
| 4 | Analog Voltage and Current |
| 5 | Solo |
| 6 | Bebop |
| 7 | SMBus-Generic |
| 8 | DroneCAN-BatteryInfo |
| 9 | ESC |
| 10 | Sum Of Selected Monitors |
| 11 | FuelFlow |
| 12 | FuelLevelPWM |
| 13 | SMBUS-SUI3 |
| 14 | SMBUS-SUI6 |
| 15 | NeoDesign |
| 16 | SMBus-Maxell |
| 17 | Generator-Elec |
| 18 | Generator-Fuel |
| 19 | Rotoye |
| 20 | MPPT |
| 21 | INA2XX |
| 22 | LTC2946 |
| 23 | Torqeedo |
| 24 | FuelLevelAnalog |
| 25 | Synthetic Current and Analog Voltage |
| 26 | INA239_SPI |
| 27 | EFI |
| 28 | AD7091R5 |
| 29 | Scripting |
| 30 | INA3221 |
Capacity of the battery in mAh when full
Battery serial number, automatically filled in for SMBus batteries, otherwise will be -1. With DroneCan it is the battery_id.
This is the timeout in seconds before a low voltage event will be triggered. For aircraft with low C batteries it may be necessary to raise this in order to cope with low voltage on long takeoffs. A value of zero disables low voltage errors.
Voltage type used for detection of low voltage event
| Value | Meaning |
|---|---|
| 0 | Raw Voltage |
| 1 | Sag Compensated Voltage |
Battery voltage that triggers a low battery failsafe. Set to 0 to disable. If the battery voltage drops below this voltage continuously for more then the period specified by the BATTC_LOW_TIMER parameter then the vehicle will perform the failsafe specified by the BATTC_FS_LOW_ACT parameter.
Battery capacity at which the low battery failsafe is triggered. Set to 0 to disable battery remaining failsafe. If the battery capacity drops below this level the vehicle will perform the failsafe specified by the BATTC_FS_LOW_ACT parameter.
Battery voltage that triggers a critical battery failsafe. Set to 0 to disable. If the battery voltage drops below this voltage continuously for more then the period specified by the BATTC_LOW_TIMER parameter then the vehicle will perform the failsafe specified by the BATTC_FS_CRT_ACT parameter.
Battery capacity at which the critical battery failsafe is triggered. Set to 0 to disable battery remaining failsafe. If the battery capacity drops below this level the vehicle will perform the failsafe specified by the BATTC_FS_CRT_ACT parameter.
What action the vehicle should perform if it hits a low battery failsafe
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Land |
What action the vehicle should perform if it hits a critical battery failsafe
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Land |
Battery voltage level which is required to arm the aircraft. Set to 0 to allow arming at any voltage.
Battery capacity remaining which is required to arm the aircraft. Set to 0 to allow arming at any capacity. Note that execept for smart batteries rebooting the vehicle will always reset the remaining capacity estimate, which can lead to this check not providing sufficent protection, it is recommended to always use this in conjunction with the BATTC_ARM_VOLT parameter.
This sets options to change the behaviour of the battery monitor
ESC Telemetry Index to write voltage, current, consumption and temperature data to. Use 0 to disable.
Sets the analog input pin that should be used for voltage monitoring.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
Sets the analog input pin that should be used for current monitoring.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 3 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 4 | CubeOrange_PM2/Navigator |
| 14 | Pixhawk2_PM2 |
| 15 | CubeOrange |
| 17 | Durandal |
| 101 | PX4-v1 |
Used to convert the voltage of the voltage sensing pin (BATTC_VOLT_PIN) to the actual battery's voltage (pin_voltage * VOLT_MULT). For the 3DR Power brick with a Pixhawk, this should be set to 10.1. For the Pixhawk with the 3DR 4in1 ESC this should be 12.02. For the PX using the PX4IO power supply this should be set to 1.
Number of amps that a 1V reading on the current sensor corresponds to. With a Pixhawk using the 3DR Power brick this should be set to 17. For the Pixhawk with the 3DR 4in1 ESC this should be 17. For Synthetic Current sensor monitors, this is the maximum, full throttle current draw.
Voltage offset at zero current on current sensor for Analog Sensors. For Synthetic Current sensor, this offset is the zero throttle system current and is added to the calculated throttle base current.
Voltage offset on voltage pin. This allows for an offset due to a diode. This voltage is subtracted before the scaling is applied.
Battery monitor I2C bus number
Battery monitor I2C address
0: sum of remaining battery monitors, If none 0 sum of specified monitors. Current will be summed and voltages averaged.
Multiplier applied to all current related reports to allow for adjustment if no UAVCAN param access or current splitting applications
The voltage seen on the analog pin when the fuel tank is empty. Note: For this type of battery monitor, the voltage seen by the analog pin is displayed as battery voltage on a GCS.
Voltage multiplier to determine what the full tank voltage reading is. This is calculated as 1 / (Voltage_Full - Voltage_Empty) Note: For this type of battery monitor, the voltage seen by the analog pin is displayed as battery voltage on a GCS.
Filter frequency in Hertz where a low pass filter is used. This is used to filter out tank slosh from the fuel level reading. A value of -1 disables the filter and unfiltered voltage is used to determine the fuel level. The suggested values at in the range of 0.2 Hz to 0.5 Hz.
Analog input pin that fuel level sensor is connected to.Analog Airspeed or RSSI ports can be used for Analog input( some autopilots provide others also). Values for some autopilots are given as examples. Search wiki for "Analog pins".
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
First order polynomial fit term
Second order polynomial fit term
Third order polynomial fit term
Offset polynomial fit term
Maximum voltage of battery. Provides scaling of current versus voltage
Battery monitor I2C bus number
Battery monitor I2C address. If this is zero then probe list of supported addresses
This controls the maximum current the INS2XX sensor will work with.
This sets the shunt resistor used in the device
If 0 all connected ESCs will be used. If non-zero, only those selected in will be used.
This controls the maximum current the INA239 sensor will work with.
This sets the shunt resistor used in the device
Battery monitor I2C bus number
Battery monitor I2C address. If this is zero then probe list of supported addresses
INA3221 channel to return data for
Sets the analog input pin that should be used for voltage monitoring on AD7091R5.
| Value | Meaning |
|---|---|
| -1 | Disabled |
Sets the analog input pin that should be used for Current monitoring on AD7091R5.
| Value | Meaning |
|---|---|
| -1 | Disabled |
Used to convert the voltage of the voltage sensing pin (BATTC_VOLT_PIN) to the actual battery's voltage (pin_voltage * VOLT_MULT).
Number of amps that a 1V reading on the current sensor corresponds to.
Voltage offset at zero current on current sensor
Voltage offset on voltage pin. This allows for an offset due to a diode. This voltage is subtracted before the scaling is applied
Controls enabling monitoring of the battery's voltage and current
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 3 | Analog Voltage Only |
| 4 | Analog Voltage and Current |
| 5 | Solo |
| 6 | Bebop |
| 7 | SMBus-Generic |
| 8 | DroneCAN-BatteryInfo |
| 9 | ESC |
| 10 | Sum Of Selected Monitors |
| 11 | FuelFlow |
| 12 | FuelLevelPWM |
| 13 | SMBUS-SUI3 |
| 14 | SMBUS-SUI6 |
| 15 | NeoDesign |
| 16 | SMBus-Maxell |
| 17 | Generator-Elec |
| 18 | Generator-Fuel |
| 19 | Rotoye |
| 20 | MPPT |
| 21 | INA2XX |
| 22 | LTC2946 |
| 23 | Torqeedo |
| 24 | FuelLevelAnalog |
| 25 | Synthetic Current and Analog Voltage |
| 26 | INA239_SPI |
| 27 | EFI |
| 28 | AD7091R5 |
| 29 | Scripting |
| 30 | INA3221 |
Capacity of the battery in mAh when full
Battery serial number, automatically filled in for SMBus batteries, otherwise will be -1. With DroneCan it is the battery_id.
This is the timeout in seconds before a low voltage event will be triggered. For aircraft with low C batteries it may be necessary to raise this in order to cope with low voltage on long takeoffs. A value of zero disables low voltage errors.
Voltage type used for detection of low voltage event
| Value | Meaning |
|---|---|
| 0 | Raw Voltage |
| 1 | Sag Compensated Voltage |
Battery voltage that triggers a low battery failsafe. Set to 0 to disable. If the battery voltage drops below this voltage continuously for more then the period specified by the BATTD_LOW_TIMER parameter then the vehicle will perform the failsafe specified by the BATTD_FS_LOW_ACT parameter.
Battery capacity at which the low battery failsafe is triggered. Set to 0 to disable battery remaining failsafe. If the battery capacity drops below this level the vehicle will perform the failsafe specified by the BATTD_FS_LOW_ACT parameter.
Battery voltage that triggers a critical battery failsafe. Set to 0 to disable. If the battery voltage drops below this voltage continuously for more then the period specified by the BATTD_LOW_TIMER parameter then the vehicle will perform the failsafe specified by the BATTD_FS_CRT_ACT parameter.
Battery capacity at which the critical battery failsafe is triggered. Set to 0 to disable battery remaining failsafe. If the battery capacity drops below this level the vehicle will perform the failsafe specified by the BATTD_FS_CRT_ACT parameter.
What action the vehicle should perform if it hits a low battery failsafe
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Land |
What action the vehicle should perform if it hits a critical battery failsafe
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Land |
Battery voltage level which is required to arm the aircraft. Set to 0 to allow arming at any voltage.
Battery capacity remaining which is required to arm the aircraft. Set to 0 to allow arming at any capacity. Note that execept for smart batteries rebooting the vehicle will always reset the remaining capacity estimate, which can lead to this check not providing sufficent protection, it is recommended to always use this in conjunction with the BATTD_ARM_VOLT parameter.
This sets options to change the behaviour of the battery monitor
ESC Telemetry Index to write voltage, current, consumption and temperature data to. Use 0 to disable.
Sets the analog input pin that should be used for voltage monitoring.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
Sets the analog input pin that should be used for current monitoring.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 3 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 4 | CubeOrange_PM2/Navigator |
| 14 | Pixhawk2_PM2 |
| 15 | CubeOrange |
| 17 | Durandal |
| 101 | PX4-v1 |
Used to convert the voltage of the voltage sensing pin (BATTD_VOLT_PIN) to the actual battery's voltage (pin_voltage * VOLT_MULT). For the 3DR Power brick with a Pixhawk, this should be set to 10.1. For the Pixhawk with the 3DR 4in1 ESC this should be 12.02. For the PX using the PX4IO power supply this should be set to 1.
Number of amps that a 1V reading on the current sensor corresponds to. With a Pixhawk using the 3DR Power brick this should be set to 17. For the Pixhawk with the 3DR 4in1 ESC this should be 17. For Synthetic Current sensor monitors, this is the maximum, full throttle current draw.
Voltage offset at zero current on current sensor for Analog Sensors. For Synthetic Current sensor, this offset is the zero throttle system current and is added to the calculated throttle base current.
Voltage offset on voltage pin. This allows for an offset due to a diode. This voltage is subtracted before the scaling is applied.
Battery monitor I2C bus number
Battery monitor I2C address
0: sum of remaining battery monitors, If none 0 sum of specified monitors. Current will be summed and voltages averaged.
Multiplier applied to all current related reports to allow for adjustment if no UAVCAN param access or current splitting applications
The voltage seen on the analog pin when the fuel tank is empty. Note: For this type of battery monitor, the voltage seen by the analog pin is displayed as battery voltage on a GCS.
Voltage multiplier to determine what the full tank voltage reading is. This is calculated as 1 / (Voltage_Full - Voltage_Empty) Note: For this type of battery monitor, the voltage seen by the analog pin is displayed as battery voltage on a GCS.
Filter frequency in Hertz where a low pass filter is used. This is used to filter out tank slosh from the fuel level reading. A value of -1 disables the filter and unfiltered voltage is used to determine the fuel level. The suggested values at in the range of 0.2 Hz to 0.5 Hz.
Analog input pin that fuel level sensor is connected to.Analog Airspeed or RSSI ports can be used for Analog input( some autopilots provide others also). Values for some autopilots are given as examples. Search wiki for "Analog pins".
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
First order polynomial fit term
Second order polynomial fit term
Third order polynomial fit term
Offset polynomial fit term
Maximum voltage of battery. Provides scaling of current versus voltage
Battery monitor I2C bus number
Battery monitor I2C address. If this is zero then probe list of supported addresses
This controls the maximum current the INS2XX sensor will work with.
This sets the shunt resistor used in the device
If 0 all connected ESCs will be used. If non-zero, only those selected in will be used.
This controls the maximum current the INA239 sensor will work with.
This sets the shunt resistor used in the device
Battery monitor I2C bus number
Battery monitor I2C address. If this is zero then probe list of supported addresses
INA3221 channel to return data for
Sets the analog input pin that should be used for voltage monitoring on AD7091R5.
| Value | Meaning |
|---|---|
| -1 | Disabled |
Sets the analog input pin that should be used for Current monitoring on AD7091R5.
| Value | Meaning |
|---|---|
| -1 | Disabled |
Used to convert the voltage of the voltage sensing pin (BATTD_VOLT_PIN) to the actual battery's voltage (pin_voltage * VOLT_MULT).
Number of amps that a 1V reading on the current sensor corresponds to.
Voltage offset at zero current on current sensor
Voltage offset on voltage pin. This allows for an offset due to a diode. This voltage is subtracted before the scaling is applied
Controls enabling monitoring of the battery's voltage and current
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 3 | Analog Voltage Only |
| 4 | Analog Voltage and Current |
| 5 | Solo |
| 6 | Bebop |
| 7 | SMBus-Generic |
| 8 | DroneCAN-BatteryInfo |
| 9 | ESC |
| 10 | Sum Of Selected Monitors |
| 11 | FuelFlow |
| 12 | FuelLevelPWM |
| 13 | SMBUS-SUI3 |
| 14 | SMBUS-SUI6 |
| 15 | NeoDesign |
| 16 | SMBus-Maxell |
| 17 | Generator-Elec |
| 18 | Generator-Fuel |
| 19 | Rotoye |
| 20 | MPPT |
| 21 | INA2XX |
| 22 | LTC2946 |
| 23 | Torqeedo |
| 24 | FuelLevelAnalog |
| 25 | Synthetic Current and Analog Voltage |
| 26 | INA239_SPI |
| 27 | EFI |
| 28 | AD7091R5 |
| 29 | Scripting |
| 30 | INA3221 |
Capacity of the battery in mAh when full
Battery serial number, automatically filled in for SMBus batteries, otherwise will be -1. With DroneCan it is the battery_id.
This is the timeout in seconds before a low voltage event will be triggered. For aircraft with low C batteries it may be necessary to raise this in order to cope with low voltage on long takeoffs. A value of zero disables low voltage errors.
Voltage type used for detection of low voltage event
| Value | Meaning |
|---|---|
| 0 | Raw Voltage |
| 1 | Sag Compensated Voltage |
Battery voltage that triggers a low battery failsafe. Set to 0 to disable. If the battery voltage drops below this voltage continuously for more then the period specified by the BATTE_LOW_TIMER parameter then the vehicle will perform the failsafe specified by the BATTE_FS_LOW_ACT parameter.
Battery capacity at which the low battery failsafe is triggered. Set to 0 to disable battery remaining failsafe. If the battery capacity drops below this level the vehicle will perform the failsafe specified by the BATTE_FS_LOW_ACT parameter.
Battery voltage that triggers a critical battery failsafe. Set to 0 to disable. If the battery voltage drops below this voltage continuously for more then the period specified by the BATTE_LOW_TIMER parameter then the vehicle will perform the failsafe specified by the BATTE_FS_CRT_ACT parameter.
Battery capacity at which the critical battery failsafe is triggered. Set to 0 to disable battery remaining failsafe. If the battery capacity drops below this level the vehicle will perform the failsafe specified by the BATTE_FS_CRT_ACT parameter.
What action the vehicle should perform if it hits a low battery failsafe
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Land |
What action the vehicle should perform if it hits a critical battery failsafe
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Land |
Battery voltage level which is required to arm the aircraft. Set to 0 to allow arming at any voltage.
Battery capacity remaining which is required to arm the aircraft. Set to 0 to allow arming at any capacity. Note that execept for smart batteries rebooting the vehicle will always reset the remaining capacity estimate, which can lead to this check not providing sufficent protection, it is recommended to always use this in conjunction with the BATTE_ARM_VOLT parameter.
This sets options to change the behaviour of the battery monitor
ESC Telemetry Index to write voltage, current, consumption and temperature data to. Use 0 to disable.
Sets the analog input pin that should be used for voltage monitoring.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
Sets the analog input pin that should be used for current monitoring.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 3 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 4 | CubeOrange_PM2/Navigator |
| 14 | Pixhawk2_PM2 |
| 15 | CubeOrange |
| 17 | Durandal |
| 101 | PX4-v1 |
Used to convert the voltage of the voltage sensing pin (BATTE_VOLT_PIN) to the actual battery's voltage (pin_voltage * VOLT_MULT). For the 3DR Power brick with a Pixhawk, this should be set to 10.1. For the Pixhawk with the 3DR 4in1 ESC this should be 12.02. For the PX using the PX4IO power supply this should be set to 1.
Number of amps that a 1V reading on the current sensor corresponds to. With a Pixhawk using the 3DR Power brick this should be set to 17. For the Pixhawk with the 3DR 4in1 ESC this should be 17. For Synthetic Current sensor monitors, this is the maximum, full throttle current draw.
Voltage offset at zero current on current sensor for Analog Sensors. For Synthetic Current sensor, this offset is the zero throttle system current and is added to the calculated throttle base current.
Voltage offset on voltage pin. This allows for an offset due to a diode. This voltage is subtracted before the scaling is applied.
Battery monitor I2C bus number
Battery monitor I2C address
0: sum of remaining battery monitors, If none 0 sum of specified monitors. Current will be summed and voltages averaged.
Multiplier applied to all current related reports to allow for adjustment if no UAVCAN param access or current splitting applications
The voltage seen on the analog pin when the fuel tank is empty. Note: For this type of battery monitor, the voltage seen by the analog pin is displayed as battery voltage on a GCS.
Voltage multiplier to determine what the full tank voltage reading is. This is calculated as 1 / (Voltage_Full - Voltage_Empty) Note: For this type of battery monitor, the voltage seen by the analog pin is displayed as battery voltage on a GCS.
Filter frequency in Hertz where a low pass filter is used. This is used to filter out tank slosh from the fuel level reading. A value of -1 disables the filter and unfiltered voltage is used to determine the fuel level. The suggested values at in the range of 0.2 Hz to 0.5 Hz.
Analog input pin that fuel level sensor is connected to.Analog Airspeed or RSSI ports can be used for Analog input( some autopilots provide others also). Values for some autopilots are given as examples. Search wiki for "Analog pins".
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
First order polynomial fit term
Second order polynomial fit term
Third order polynomial fit term
Offset polynomial fit term
Maximum voltage of battery. Provides scaling of current versus voltage
Battery monitor I2C bus number
Battery monitor I2C address. If this is zero then probe list of supported addresses
This controls the maximum current the INS2XX sensor will work with.
This sets the shunt resistor used in the device
If 0 all connected ESCs will be used. If non-zero, only those selected in will be used.
This controls the maximum current the INA239 sensor will work with.
This sets the shunt resistor used in the device
Battery monitor I2C bus number
Battery monitor I2C address. If this is zero then probe list of supported addresses
INA3221 channel to return data for
Sets the analog input pin that should be used for voltage monitoring on AD7091R5.
| Value | Meaning |
|---|---|
| -1 | Disabled |
Sets the analog input pin that should be used for Current monitoring on AD7091R5.
| Value | Meaning |
|---|---|
| -1 | Disabled |
Used to convert the voltage of the voltage sensing pin (BATTE_VOLT_PIN) to the actual battery's voltage (pin_voltage * VOLT_MULT).
Number of amps that a 1V reading on the current sensor corresponds to.
Voltage offset at zero current on current sensor
Voltage offset on voltage pin. This allows for an offset due to a diode. This voltage is subtracted before the scaling is applied
Controls enabling monitoring of the battery's voltage and current
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 3 | Analog Voltage Only |
| 4 | Analog Voltage and Current |
| 5 | Solo |
| 6 | Bebop |
| 7 | SMBus-Generic |
| 8 | DroneCAN-BatteryInfo |
| 9 | ESC |
| 10 | Sum Of Selected Monitors |
| 11 | FuelFlow |
| 12 | FuelLevelPWM |
| 13 | SMBUS-SUI3 |
| 14 | SMBUS-SUI6 |
| 15 | NeoDesign |
| 16 | SMBus-Maxell |
| 17 | Generator-Elec |
| 18 | Generator-Fuel |
| 19 | Rotoye |
| 20 | MPPT |
| 21 | INA2XX |
| 22 | LTC2946 |
| 23 | Torqeedo |
| 24 | FuelLevelAnalog |
| 25 | Synthetic Current and Analog Voltage |
| 26 | INA239_SPI |
| 27 | EFI |
| 28 | AD7091R5 |
| 29 | Scripting |
| 30 | INA3221 |
Capacity of the battery in mAh when full
Battery serial number, automatically filled in for SMBus batteries, otherwise will be -1. With DroneCan it is the battery_id.
This is the timeout in seconds before a low voltage event will be triggered. For aircraft with low C batteries it may be necessary to raise this in order to cope with low voltage on long takeoffs. A value of zero disables low voltage errors.
Voltage type used for detection of low voltage event
| Value | Meaning |
|---|---|
| 0 | Raw Voltage |
| 1 | Sag Compensated Voltage |
Battery voltage that triggers a low battery failsafe. Set to 0 to disable. If the battery voltage drops below this voltage continuously for more then the period specified by the BATTF_LOW_TIMER parameter then the vehicle will perform the failsafe specified by the BATTF_FS_LOW_ACT parameter.
Battery capacity at which the low battery failsafe is triggered. Set to 0 to disable battery remaining failsafe. If the battery capacity drops below this level the vehicle will perform the failsafe specified by the BATTF_FS_LOW_ACT parameter.
Battery voltage that triggers a critical battery failsafe. Set to 0 to disable. If the battery voltage drops below this voltage continuously for more then the period specified by the BATTF_LOW_TIMER parameter then the vehicle will perform the failsafe specified by the BATTF_FS_CRT_ACT parameter.
Battery capacity at which the critical battery failsafe is triggered. Set to 0 to disable battery remaining failsafe. If the battery capacity drops below this level the vehicle will perform the failsafe specified by the BATTF_FS_CRT_ACT parameter.
What action the vehicle should perform if it hits a low battery failsafe
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Land |
What action the vehicle should perform if it hits a critical battery failsafe
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Land |
Battery voltage level which is required to arm the aircraft. Set to 0 to allow arming at any voltage.
Battery capacity remaining which is required to arm the aircraft. Set to 0 to allow arming at any capacity. Note that execept for smart batteries rebooting the vehicle will always reset the remaining capacity estimate, which can lead to this check not providing sufficent protection, it is recommended to always use this in conjunction with the BATTF_ARM_VOLT parameter.
This sets options to change the behaviour of the battery monitor
ESC Telemetry Index to write voltage, current, consumption and temperature data to. Use 0 to disable.
Sets the analog input pin that should be used for voltage monitoring.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
Sets the analog input pin that should be used for current monitoring.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 3 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 4 | CubeOrange_PM2/Navigator |
| 14 | Pixhawk2_PM2 |
| 15 | CubeOrange |
| 17 | Durandal |
| 101 | PX4-v1 |
Used to convert the voltage of the voltage sensing pin (BATTF_VOLT_PIN) to the actual battery's voltage (pin_voltage * VOLT_MULT). For the 3DR Power brick with a Pixhawk, this should be set to 10.1. For the Pixhawk with the 3DR 4in1 ESC this should be 12.02. For the PX using the PX4IO power supply this should be set to 1.
Number of amps that a 1V reading on the current sensor corresponds to. With a Pixhawk using the 3DR Power brick this should be set to 17. For the Pixhawk with the 3DR 4in1 ESC this should be 17. For Synthetic Current sensor monitors, this is the maximum, full throttle current draw.
Voltage offset at zero current on current sensor for Analog Sensors. For Synthetic Current sensor, this offset is the zero throttle system current and is added to the calculated throttle base current.
Voltage offset on voltage pin. This allows for an offset due to a diode. This voltage is subtracted before the scaling is applied.
Battery monitor I2C bus number
Battery monitor I2C address
0: sum of remaining battery monitors, If none 0 sum of specified monitors. Current will be summed and voltages averaged.
Multiplier applied to all current related reports to allow for adjustment if no UAVCAN param access or current splitting applications
The voltage seen on the analog pin when the fuel tank is empty. Note: For this type of battery monitor, the voltage seen by the analog pin is displayed as battery voltage on a GCS.
Voltage multiplier to determine what the full tank voltage reading is. This is calculated as 1 / (Voltage_Full - Voltage_Empty) Note: For this type of battery monitor, the voltage seen by the analog pin is displayed as battery voltage on a GCS.
Filter frequency in Hertz where a low pass filter is used. This is used to filter out tank slosh from the fuel level reading. A value of -1 disables the filter and unfiltered voltage is used to determine the fuel level. The suggested values at in the range of 0.2 Hz to 0.5 Hz.
Analog input pin that fuel level sensor is connected to.Analog Airspeed or RSSI ports can be used for Analog input( some autopilots provide others also). Values for some autopilots are given as examples. Search wiki for "Analog pins".
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
First order polynomial fit term
Second order polynomial fit term
Third order polynomial fit term
Offset polynomial fit term
Maximum voltage of battery. Provides scaling of current versus voltage
Battery monitor I2C bus number
Battery monitor I2C address. If this is zero then probe list of supported addresses
This controls the maximum current the INS2XX sensor will work with.
This sets the shunt resistor used in the device
If 0 all connected ESCs will be used. If non-zero, only those selected in will be used.
This controls the maximum current the INA239 sensor will work with.
This sets the shunt resistor used in the device
Battery monitor I2C bus number
Battery monitor I2C address. If this is zero then probe list of supported addresses
INA3221 channel to return data for
Sets the analog input pin that should be used for voltage monitoring on AD7091R5.
| Value | Meaning |
|---|---|
| -1 | Disabled |
Sets the analog input pin that should be used for Current monitoring on AD7091R5.
| Value | Meaning |
|---|---|
| -1 | Disabled |
Used to convert the voltage of the voltage sensing pin (BATTF_VOLT_PIN) to the actual battery's voltage (pin_voltage * VOLT_MULT).
Number of amps that a 1V reading on the current sensor corresponds to.
Voltage offset at zero current on current sensor
Voltage offset on voltage pin. This allows for an offset due to a diode. This voltage is subtracted before the scaling is applied
Controls enabling monitoring of the battery's voltage and current
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 3 | Analog Voltage Only |
| 4 | Analog Voltage and Current |
| 5 | Solo |
| 6 | Bebop |
| 7 | SMBus-Generic |
| 8 | DroneCAN-BatteryInfo |
| 9 | ESC |
| 10 | Sum Of Selected Monitors |
| 11 | FuelFlow |
| 12 | FuelLevelPWM |
| 13 | SMBUS-SUI3 |
| 14 | SMBUS-SUI6 |
| 15 | NeoDesign |
| 16 | SMBus-Maxell |
| 17 | Generator-Elec |
| 18 | Generator-Fuel |
| 19 | Rotoye |
| 20 | MPPT |
| 21 | INA2XX |
| 22 | LTC2946 |
| 23 | Torqeedo |
| 24 | FuelLevelAnalog |
| 25 | Synthetic Current and Analog Voltage |
| 26 | INA239_SPI |
| 27 | EFI |
| 28 | AD7091R5 |
| 29 | Scripting |
| 30 | INA3221 |
Capacity of the battery in mAh when full
Battery serial number, automatically filled in for SMBus batteries, otherwise will be -1. With DroneCan it is the battery_id.
This is the timeout in seconds before a low voltage event will be triggered. For aircraft with low C batteries it may be necessary to raise this in order to cope with low voltage on long takeoffs. A value of zero disables low voltage errors.
Voltage type used for detection of low voltage event
| Value | Meaning |
|---|---|
| 0 | Raw Voltage |
| 1 | Sag Compensated Voltage |
Battery voltage that triggers a low battery failsafe. Set to 0 to disable. If the battery voltage drops below this voltage continuously for more then the period specified by the BATTG_LOW_TIMER parameter then the vehicle will perform the failsafe specified by the BATTG_FS_LOW_ACT parameter.
Battery capacity at which the low battery failsafe is triggered. Set to 0 to disable battery remaining failsafe. If the battery capacity drops below this level the vehicle will perform the failsafe specified by the BATTG_FS_LOW_ACT parameter.
Battery voltage that triggers a critical battery failsafe. Set to 0 to disable. If the battery voltage drops below this voltage continuously for more then the period specified by the BATTG_LOW_TIMER parameter then the vehicle will perform the failsafe specified by the BATTG_FS_CRT_ACT parameter.
Battery capacity at which the critical battery failsafe is triggered. Set to 0 to disable battery remaining failsafe. If the battery capacity drops below this level the vehicle will perform the failsafe specified by the BATTG_FS_CRT_ACT parameter.
What action the vehicle should perform if it hits a low battery failsafe
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Land |
What action the vehicle should perform if it hits a critical battery failsafe
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Land |
Battery voltage level which is required to arm the aircraft. Set to 0 to allow arming at any voltage.
Battery capacity remaining which is required to arm the aircraft. Set to 0 to allow arming at any capacity. Note that execept for smart batteries rebooting the vehicle will always reset the remaining capacity estimate, which can lead to this check not providing sufficent protection, it is recommended to always use this in conjunction with the BATTG_ARM_VOLT parameter.
This sets options to change the behaviour of the battery monitor
ESC Telemetry Index to write voltage, current, consumption and temperature data to. Use 0 to disable.
Sets the analog input pin that should be used for voltage monitoring.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
Sets the analog input pin that should be used for current monitoring.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 3 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 4 | CubeOrange_PM2/Navigator |
| 14 | Pixhawk2_PM2 |
| 15 | CubeOrange |
| 17 | Durandal |
| 101 | PX4-v1 |
Used to convert the voltage of the voltage sensing pin (BATTG_VOLT_PIN) to the actual battery's voltage (pin_voltage * VOLT_MULT). For the 3DR Power brick with a Pixhawk, this should be set to 10.1. For the Pixhawk with the 3DR 4in1 ESC this should be 12.02. For the PX using the PX4IO power supply this should be set to 1.
Number of amps that a 1V reading on the current sensor corresponds to. With a Pixhawk using the 3DR Power brick this should be set to 17. For the Pixhawk with the 3DR 4in1 ESC this should be 17. For Synthetic Current sensor monitors, this is the maximum, full throttle current draw.
Voltage offset at zero current on current sensor for Analog Sensors. For Synthetic Current sensor, this offset is the zero throttle system current and is added to the calculated throttle base current.
Voltage offset on voltage pin. This allows for an offset due to a diode. This voltage is subtracted before the scaling is applied.
Battery monitor I2C bus number
Battery monitor I2C address
0: sum of remaining battery monitors, If none 0 sum of specified monitors. Current will be summed and voltages averaged.
Multiplier applied to all current related reports to allow for adjustment if no UAVCAN param access or current splitting applications
The voltage seen on the analog pin when the fuel tank is empty. Note: For this type of battery monitor, the voltage seen by the analog pin is displayed as battery voltage on a GCS.
Voltage multiplier to determine what the full tank voltage reading is. This is calculated as 1 / (Voltage_Full - Voltage_Empty) Note: For this type of battery monitor, the voltage seen by the analog pin is displayed as battery voltage on a GCS.
Filter frequency in Hertz where a low pass filter is used. This is used to filter out tank slosh from the fuel level reading. A value of -1 disables the filter and unfiltered voltage is used to determine the fuel level. The suggested values at in the range of 0.2 Hz to 0.5 Hz.
Analog input pin that fuel level sensor is connected to.Analog Airspeed or RSSI ports can be used for Analog input( some autopilots provide others also). Values for some autopilots are given as examples. Search wiki for "Analog pins".
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
First order polynomial fit term
Second order polynomial fit term
Third order polynomial fit term
Offset polynomial fit term
Maximum voltage of battery. Provides scaling of current versus voltage
Battery monitor I2C bus number
Battery monitor I2C address. If this is zero then probe list of supported addresses
This controls the maximum current the INS2XX sensor will work with.
This sets the shunt resistor used in the device
If 0 all connected ESCs will be used. If non-zero, only those selected in will be used.
This controls the maximum current the INA239 sensor will work with.
This sets the shunt resistor used in the device
Battery monitor I2C bus number
Battery monitor I2C address. If this is zero then probe list of supported addresses
INA3221 channel to return data for
Sets the analog input pin that should be used for voltage monitoring on AD7091R5.
| Value | Meaning |
|---|---|
| -1 | Disabled |
Sets the analog input pin that should be used for Current monitoring on AD7091R5.
| Value | Meaning |
|---|---|
| -1 | Disabled |
Used to convert the voltage of the voltage sensing pin (BATTG_VOLT_PIN) to the actual battery's voltage (pin_voltage * VOLT_MULT).
Number of amps that a 1V reading on the current sensor corresponds to.
Voltage offset at zero current on current sensor
Voltage offset on voltage pin. This allows for an offset due to a diode. This voltage is subtracted before the scaling is applied
Controls enabling monitoring of the battery's voltage and current
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 3 | Analog Voltage Only |
| 4 | Analog Voltage and Current |
| 5 | Solo |
| 6 | Bebop |
| 7 | SMBus-Generic |
| 8 | DroneCAN-BatteryInfo |
| 9 | ESC |
| 10 | Sum Of Selected Monitors |
| 11 | FuelFlow |
| 12 | FuelLevelPWM |
| 13 | SMBUS-SUI3 |
| 14 | SMBUS-SUI6 |
| 15 | NeoDesign |
| 16 | SMBus-Maxell |
| 17 | Generator-Elec |
| 18 | Generator-Fuel |
| 19 | Rotoye |
| 20 | MPPT |
| 21 | INA2XX |
| 22 | LTC2946 |
| 23 | Torqeedo |
| 24 | FuelLevelAnalog |
| 25 | Synthetic Current and Analog Voltage |
| 26 | INA239_SPI |
| 27 | EFI |
| 28 | AD7091R5 |
| 29 | Scripting |
| 30 | INA3221 |
Capacity of the battery in mAh when full
Battery serial number, automatically filled in for SMBus batteries, otherwise will be -1. With DroneCan it is the battery_id.
This is the timeout in seconds before a low voltage event will be triggered. For aircraft with low C batteries it may be necessary to raise this in order to cope with low voltage on long takeoffs. A value of zero disables low voltage errors.
Voltage type used for detection of low voltage event
| Value | Meaning |
|---|---|
| 0 | Raw Voltage |
| 1 | Sag Compensated Voltage |
Battery voltage that triggers a low battery failsafe. Set to 0 to disable. If the battery voltage drops below this voltage continuously for more then the period specified by the BATT_LOW_TIMER parameter then the vehicle will perform the failsafe specified by the BATT_FS_LOW_ACT parameter.
Battery capacity at which the low battery failsafe is triggered. Set to 0 to disable battery remaining failsafe. If the battery capacity drops below this level the vehicle will perform the failsafe specified by the BATT_FS_LOW_ACT parameter.
Battery voltage that triggers a critical battery failsafe. Set to 0 to disable. If the battery voltage drops below this voltage continuously for more then the period specified by the BATT_LOW_TIMER parameter then the vehicle will perform the failsafe specified by the BATT_FS_CRT_ACT parameter.
Battery capacity at which the critical battery failsafe is triggered. Set to 0 to disable battery remaining failsafe. If the battery capacity drops below this level the vehicle will perform the failsafe specified by the BATT_FS_CRT_ACT parameter.
What action the vehicle should perform if it hits a low battery failsafe
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Land |
What action the vehicle should perform if it hits a critical battery failsafe
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Land |
Battery voltage level which is required to arm the aircraft. Set to 0 to allow arming at any voltage.
Battery capacity remaining which is required to arm the aircraft. Set to 0 to allow arming at any capacity. Note that execept for smart batteries rebooting the vehicle will always reset the remaining capacity estimate, which can lead to this check not providing sufficent protection, it is recommended to always use this in conjunction with the BATT_ARM_VOLT parameter.
This sets options to change the behaviour of the battery monitor
ESC Telemetry Index to write voltage, current, consumption and temperature data to. Use 0 to disable.
Sets the analog input pin that should be used for voltage monitoring.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
Sets the analog input pin that should be used for current monitoring.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 3 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 4 | CubeOrange_PM2/Navigator |
| 14 | Pixhawk2_PM2 |
| 15 | CubeOrange |
| 17 | Durandal |
| 101 | PX4-v1 |
Used to convert the voltage of the voltage sensing pin (BATT_VOLT_PIN) to the actual battery's voltage (pin_voltage * VOLT_MULT). For the 3DR Power brick with a Pixhawk, this should be set to 10.1. For the Pixhawk with the 3DR 4in1 ESC this should be 12.02. For the PX using the PX4IO power supply this should be set to 1.
Number of amps that a 1V reading on the current sensor corresponds to. With a Pixhawk using the 3DR Power brick this should be set to 17. For the Pixhawk with the 3DR 4in1 ESC this should be 17. For Synthetic Current sensor monitors, this is the maximum, full throttle current draw.
Voltage offset at zero current on current sensor for Analog Sensors. For Synthetic Current sensor, this offset is the zero throttle system current and is added to the calculated throttle base current.
Voltage offset on voltage pin. This allows for an offset due to a diode. This voltage is subtracted before the scaling is applied.
Battery monitor I2C bus number
Battery monitor I2C address
0: sum of remaining battery monitors, If none 0 sum of specified monitors. Current will be summed and voltages averaged.
Multiplier applied to all current related reports to allow for adjustment if no UAVCAN param access or current splitting applications
The voltage seen on the analog pin when the fuel tank is empty. Note: For this type of battery monitor, the voltage seen by the analog pin is displayed as battery voltage on a GCS.
Voltage multiplier to determine what the full tank voltage reading is. This is calculated as 1 / (Voltage_Full - Voltage_Empty) Note: For this type of battery monitor, the voltage seen by the analog pin is displayed as battery voltage on a GCS.
Filter frequency in Hertz where a low pass filter is used. This is used to filter out tank slosh from the fuel level reading. A value of -1 disables the filter and unfiltered voltage is used to determine the fuel level. The suggested values at in the range of 0.2 Hz to 0.5 Hz.
Analog input pin that fuel level sensor is connected to.Analog Airspeed or RSSI ports can be used for Analog input( some autopilots provide others also). Values for some autopilots are given as examples. Search wiki for "Analog pins".
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
First order polynomial fit term
Second order polynomial fit term
Third order polynomial fit term
Offset polynomial fit term
Maximum voltage of battery. Provides scaling of current versus voltage
Battery monitor I2C bus number
Battery monitor I2C address. If this is zero then probe list of supported addresses
This controls the maximum current the INS2XX sensor will work with.
This sets the shunt resistor used in the device
If 0 all connected ESCs will be used. If non-zero, only those selected in will be used.
This controls the maximum current the INA239 sensor will work with.
This sets the shunt resistor used in the device
Battery monitor I2C bus number
Battery monitor I2C address. If this is zero then probe list of supported addresses
INA3221 channel to return data for
Sets the analog input pin that should be used for voltage monitoring on AD7091R5.
| Value | Meaning |
|---|---|
| -1 | Disabled |
Sets the analog input pin that should be used for Current monitoring on AD7091R5.
| Value | Meaning |
|---|---|
| -1 | Disabled |
Used to convert the voltage of the voltage sensing pin (BATT_VOLT_PIN) to the actual battery's voltage (pin_voltage * VOLT_MULT).
Number of amps that a 1V reading on the current sensor corresponds to.
Voltage offset at zero current on current sensor
Voltage offset on voltage pin. This allows for an offset due to a diode. This voltage is subtracted before the scaling is applied
Enable flow control on serial 1 (telemetry 1). You must have the RTS and CTS pins connected to your radio. The standard DF13 6 pin connector for a 3DR radio does have those pins connected. If this is set to 2 then flow control will be auto-detected by checking for the output buffer filling on startup. Note that the PX4v1 does not have hardware flow control pins on this port, so you should leave this disabled.
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
| 2 | Auto |
| 3 | RS-485 Driver enable RTS pin |
Enable flow control on serial 2 (telemetry 2). You must have the RTS and CTS pins connected to your radio. The standard DF13 6 pin connector for a 3DR radio does have those pins connected. If this is set to 2 then flow control will be auto-detected by checking for the output buffer filling on startup.
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
| 2 | Auto |
| 3 | RS-485 Driver enable RTS pin |
Enable flow control on serial 3. You must have the RTS and CTS pins connected to your radio. The standard DF13 6 pin connector for a 3DR radio does have those pins connected. If this is set to 2 then flow control will be auto-detected by checking for the output buffer filling on startup.
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
| 2 | Auto |
| 3 | RS-485 Driver enable RTS pin |
Enable flow control on serial 4. You must have the RTS and CTS pins connected to your radio. The standard DF13 6 pin connector for a 3DR radio does have those pins connected. If this is set to 2 then flow control will be auto-detected by checking for the output buffer filling on startup.
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
| 2 | Auto |
| 3 | RS-485 Driver enable RTS pin |
Enable flow control on serial 5. You must have the RTS and CTS pins connected to your radio. The standard DF13 6 pin connector for a 3DR radio does have those pins connected. If this is set to 2 then flow control will be auto-detected by checking for the output buffer filling on startup.
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
| 2 | Auto |
| 3 | RS-485 Driver enable RTS pin |
Enable flow control on serial 6. You must have the RTS and CTS pins connected to your radio. The standard DF13 6 pin connector for a 3DR radio does have those pins connected. If this is set to 2 then flow control will be auto-detected by checking for the output buffer filling on startup.
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
| 2 | Auto |
| 3 | RS-485 Driver enable RTS pin |
Enable flow control on serial 7. You must have the RTS and CTS pins connected to your radio. The standard DF13 6 pin connector for a 3DR radio does have those pins connected. If this is set to 2 then flow control will be auto-detected by checking for the output buffer filling on startup.
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
| 2 | Auto |
| 3 | RS-485 Driver enable RTS pin |
Enable flow control on serial 8. You must have the RTS and CTS pins connected to your radio. The standard DF13 6 pin connector for a 3DR radio does have those pins connected. If this is set to 2 then flow control will be auto-detected by checking for the output buffer filling on startup.
This controls the default state of the safety switch at startup. When set to 1 the safety switch will start in the safe state (flashing) at boot. When set to zero the safety switch will start in the unsafe state (solid) at startup. Note that if a safety switch is fitted the user can still control the safety state after startup using the switch. The safety state can also be controlled in software using a MAVLink message.
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
This sets the SBUS output frame rate in Hz
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | 50Hz |
| 2 | 75Hz |
| 3 | 100Hz |
| 4 | 150Hz |
| 5 | 200Hz |
| 6 | 250Hz |
| 7 | 300Hz |
User-defined serial number of this vehicle, it can be any arbitrary number you want and has no effect on the autopilot
A bitmask which controls what outputs can move while the safety switch has not been pressed
Board heater target temperature for boards with controllable heating units. Set to -1 to disable the heater, please reboot after setting to -1.
This allows selection of a PX4 or VRBRAIN board type. If set to zero then the board type is auto-detected (PX4)
| Value | Meaning |
|---|---|
| 0 | AUTO |
| 1 | PX4V1 |
| 2 | Pixhawk |
| 3 | Cube/Pixhawk2 |
| 5 | PixhawkMini |
| 6 | Pixhawk2Slim |
| 13 | Intel Aero FC |
| 14 | Pixhawk Pro |
| 20 | AUAV2.1 |
| 22 | MINDPXV2 |
| 24 | CUAVv5/FMUV5 |
| 39 | PX4 FMUV6 |
| 100 | PX4 OLDDRIVERS |
This allows for the IO co-processor on boards with an IOMCU to be disabled. Setting to 2 will enable the IOMCU but not attempt to update firmware on startup
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
| 2 | EnableNoFWUpdate |
This controls the activation of the safety button. It allows you to control if the safety button can be used for safety enable and/or disable, and whether the button is only active when disarmed
Minimum voltage on the autopilot power rail to allow the aircraft to arm. 0 to disable the check.
Minimum voltage on the servo rail to allow the aircraft to arm. 0 to disable the check.
This is a scaling factor to slow down microSD operation. It can be used on flight board and microSD card combinations where full speed is not reliable. For normal full speed operation a value of 0 should be used.
This sets the voltage max for PWM output pulses. 0 for 3.3V and 1 for 5V output. On boards with an IOMCU that support this parameter this option only affects the 8 main outputs, not the 6 auxiliary outputs. Using 5V output can help to reduce the impact of ESC noise interference corrupting signals to the ESCs.
| Value | Meaning |
|---|---|
| 0 | 3.3V |
| 1 | 5V |
Board specific option flags
This adds a delay in milliseconds to boot to ensure peripherals initialise fully
Board Heater P gain
Board Heater integrator gain
Board Heater integrator maximum
Select an alternative hardware configuration. A value of zero selects the default configuration for this board. Other values are board specific. Please see the documentation for your board for details on any alternative configuration values that may be available.
Arming check will fail if temp is lower than this margin below BRD_HEAT_TARG. 0 disables the low temperature check
This sets the amount of storage in kilobytes reserved on the microsd card in mission.stg for waypoint storage. Each waypoint uses 15 bytes.
This sets the amount of storage in kilobytes reserved on the microsd card in fence.stg for fence storage.
This loads the DShot firmware on the IO co-processor
| Value | Meaning |
|---|---|
| 0 | StandardFW |
| 1 | DshotFW |
This enables support for direct attached radio receivers
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | CYRF6936 |
| 2 | CC2500 |
| 3 | BK2425 |
Select air protocol
| Value | Meaning |
|---|---|
| 0 | Auto |
| 1 | DSM2 |
| 2 | DSMX |
radio debug level
disable receive CRC (for debug)
| Value | Meaning |
|---|---|
| 0 | NotDisabled |
| 1 | Disabled |
Channel to show receive RSSI signal strength, or zero for disabled
Channel to show received packet-per-second rate, or zero for disabled
If this is non-zero then telemetry packets will be sent over DSM
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
Set telemetry transmit power. This is the power level (from 1 to 8) for telemetry packets sent from the RX to the TX
If this is enabled then the radio will continuously transmit as required for FCC testing. The transmit channel is set by the value of the parameter. The radio will not work for RC input while this is enabled
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | MinChannel |
| 2 | MidChannel |
| 3 | MaxChannel |
| 4 | MinChannelCW |
| 5 | MidChannelCW |
| 6 | MaxChannelCW |
This selects between different stick input modes. The default is mode2, which has throttle on the left stick and pitch on the right stick. You can instead set mode1, which has throttle on the right stick and pitch on the left stick.
| Value | Meaning |
|---|---|
| 1 | Mode1 |
| 2 | Mode2 |
This sets the radio to a fixed test channel for factory testing. Using a fixed channel avoids the need for binding in factory testing.
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | TestChan1 |
| 2 | TestChan2 |
| 3 | TestChan3 |
| 4 | TestChan4 |
| 5 | TestChan5 |
| 6 | TestChan6 |
| 7 | TestChan7 |
| 8 | TestChan8 |
Channel to show telemetry RSSI value as received by TX
Channel to show telemetry packets-per-second value, as received at TX
Set transmitter maximum transmit power (from 1 to 8)
Set transmitter buzzer note adjustment (adjust frequency up)
When non-zero this sets the time with no transmitter packets before we start looking for auto-bind packets.
This sets the minimum RSSI of an auto-bind packet for it to be accepted. This should be set so that auto-bind will only happen at short range to minimise the change of an auto-bind happening accidentially
Specifies which sources of UTC time will be accepted
Adds offset in +- minutes from UTC to calculate local time
Loglevel for recording initialisation and debug information from CAN Interface
| Value | Meaning |
|---|---|
| 0 | Log None |
| 1 | Log Error |
| 2 | Log Warning and below |
| 3 | Log Info and below |
| 4 | Log Everything |
Enabling this option starts selected protocol that will use this virtual driver
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | DroneCAN |
| 4 | PiccoloCAN |
| 6 | EFI_NWPMU |
| 7 | USD1 |
| 8 | KDECAN |
| 10 | Scripting |
| 11 | Benewake |
| 12 | Scripting2 |
| 13 | TOFSenseP |
| 14 | RadarCAN (NanoRadar/Hexsoon) |
Secondary protocol with 11 bit CAN addressing
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 7 | USD1 |
| 10 | Scripting |
| 11 | Benewake |
| 12 | Scripting2 |
| 13 | TOFSenseP |
| 14 | RadarCAN (NanoRadar/Hexsoon) |
Bitmask defining which ESC (motor) channels are to be transmitted over Piccolo CAN
Output rate of ESC command messages
Bitmask defining which servo channels are to be transmitted over Piccolo CAN
Output rate of servo command messages
Node ID to send ECU throttle messages to. Set to zero to disable ECU throttle messages. Set to 255 to broadcast to all ECUs.
Output rate of ECU command messages
DroneCAN node ID used by the driver itself on this network
Bitmask with one set for channel to be transmitted as a servo command over DroneCAN
Bitmask with one set for channel to be transmitted as a ESC command over DroneCAN
Maximum transmit rate for servo outputs
Option flags
Maximum transmit rate for Notify State Message
Offset for ESC numbering in DroneCAN ESC RawCommand messages. This allows for more efficient packing of ESC command messages. If your ESCs are on servo outputs 5 to 8 and you set this parameter to 4 then the ESC RawCommand will be sent with the first 4 slots filled. This can be used for more efficient usage of CAN bandwidth
Amount of memory in bytes to allocate for the DroneCAN memory pool. More memory is needed for higher CAN bus loads
Bitmask with one set for each output channel that uses a reversible ESC over DroneCAN. Reversible ESCs use both positive and negative values in RawCommands, with positive commanding the forward direction and negative commanding the reverse direction.
Maximum transmit rate for relay outputs, note that this rate is per message each message does 1 relay, so if with more relays will take longer to update at the same rate, a extra message will be sent when a relay changes state
Enable DroneCAN virtual serial ports
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
CAN remote node number for serial port
Serial port number on remote CAN node
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 0 | Serial0 |
| 1 | Serial1 |
| 2 | Serial2 |
| 3 | Serial3 |
| 4 | Serial4 |
| 5 | Serial5 |
| 6 | Serial6 |
Serial baud rate on remote CAN node
| Value | Meaning |
|---|---|
| 1 | 1200 |
| 2 | 2400 |
| 4 | 4800 |
| 9 | 9600 |
| 19 | 19200 |
| 38 | 38400 |
| 57 | 57600 |
| 111 | 111100 |
| 115 | 115200 |
| 230 | 230400 |
| 256 | 256000 |
| 460 | 460800 |
| 500 | 500000 |
| 921 | 921600 |
| 1500 | 1.5MBaud |
| 2000 | 2MBaud |
| 12500000 | 12.5MBaud |
Serial protocol of DroneCAN serial port
| Value | Meaning |
|---|---|
| -1 | None |
| 1 | MAVLink1 |
| 2 | MAVLink2 |
| 3 | Frsky D |
| 4 | Frsky SPort |
| 5 | GPS |
| 7 | Alexmos Gimbal Serial |
| 8 | Gimbal |
| 9 | Rangefinder |
| 10 | FrSky SPort Passthrough (OpenTX) |
| 11 | Lidar360 |
| 13 | Beacon |
| 14 | Volz servo out |
| 15 | SBus servo out |
| 16 | ESC Telemetry |
| 17 | Devo Telemetry |
| 18 | OpticalFlow |
| 19 | RobotisServo |
| 20 | NMEA Output |
| 21 | WindVane |
| 22 | SLCAN |
| 23 | RCIN |
| 24 | EFI Serial |
| 25 | LTM |
| 26 | RunCam |
| 27 | HottTelem |
| 28 | Scripting |
| 29 | Crossfire VTX |
| 30 | Generator |
| 31 | Winch |
| 32 | MSP |
| 33 | DJI FPV |
| 34 | AirSpeed |
| 35 | ADSB |
| 36 | AHRS |
| 37 | SmartAudio |
| 38 | FETtecOneWire |
| 39 | Torqeedo |
| 40 | AIS |
| 41 | CoDevESC |
| 42 | DisplayPort |
| 43 | MAVLink High Latency |
| 44 | IRC Tramp |
| 45 | DDS XRCE |
| 46 | IMUDATA |
| 48 | PPP |
| 49 | i-BUS Telemetry |
| 50 | IOMCU |
CAN remote node number for serial port
Serial port number on remote CAN node
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 0 | Serial0 |
| 1 | Serial1 |
| 2 | Serial2 |
| 3 | Serial3 |
| 4 | Serial4 |
| 5 | Serial5 |
| 6 | Serial6 |
Serial baud rate on remote CAN node
| Value | Meaning |
|---|---|
| 1 | 1200 |
| 2 | 2400 |
| 4 | 4800 |
| 9 | 9600 |
| 19 | 19200 |
| 38 | 38400 |
| 57 | 57600 |
| 111 | 111100 |
| 115 | 115200 |
| 230 | 230400 |
| 256 | 256000 |
| 460 | 460800 |
| 500 | 500000 |
| 921 | 921600 |
| 1500 | 1.5MBaud |
| 2000 | 2MBaud |
| 12500000 | 12.5MBaud |
Serial protocol of DroneCAN serial port
| Value | Meaning |
|---|---|
| -1 | None |
| 1 | MAVLink1 |
| 2 | MAVLink2 |
| 3 | Frsky D |
| 4 | Frsky SPort |
| 5 | GPS |
| 7 | Alexmos Gimbal Serial |
| 8 | Gimbal |
| 9 | Rangefinder |
| 10 | FrSky SPort Passthrough (OpenTX) |
| 11 | Lidar360 |
| 13 | Beacon |
| 14 | Volz servo out |
| 15 | SBus servo out |
| 16 | ESC Telemetry |
| 17 | Devo Telemetry |
| 18 | OpticalFlow |
| 19 | RobotisServo |
| 20 | NMEA Output |
| 21 | WindVane |
| 22 | SLCAN |
| 23 | RCIN |
| 24 | EFI Serial |
| 25 | LTM |
| 26 | RunCam |
| 27 | HottTelem |
| 28 | Scripting |
| 29 | Crossfire VTX |
| 30 | Generator |
| 31 | Winch |
| 32 | MSP |
| 33 | DJI FPV |
| 34 | AirSpeed |
| 35 | ADSB |
| 36 | AHRS |
| 37 | SmartAudio |
| 38 | FETtecOneWire |
| 39 | Torqeedo |
| 40 | AIS |
| 41 | CoDevESC |
| 42 | DisplayPort |
| 43 | MAVLink High Latency |
| 44 | IRC Tramp |
| 45 | DDS XRCE |
| 46 | IMUDATA |
| 48 | PPP |
| 49 | i-BUS Telemetry |
| 50 | IOMCU |
CAN node number for serial port
Serial port number on remote CAN node
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 0 | Serial0 |
| 1 | Serial1 |
| 2 | Serial2 |
| 3 | Serial3 |
| 4 | Serial4 |
| 5 | Serial5 |
| 6 | Serial6 |
Serial baud rate on remote CAN node
| Value | Meaning |
|---|---|
| 1 | 1200 |
| 2 | 2400 |
| 4 | 4800 |
| 9 | 9600 |
| 19 | 19200 |
| 38 | 38400 |
| 57 | 57600 |
| 111 | 111100 |
| 115 | 115200 |
| 230 | 230400 |
| 256 | 256000 |
| 460 | 460800 |
| 500 | 500000 |
| 921 | 921600 |
| 1500 | 1.5MBaud |
| 2000 | 2MBaud |
| 12500000 | 12.5MBaud |
Serial protocol of DroneCAN serial port
| Value | Meaning |
|---|---|
| -1 | None |
| 1 | MAVLink1 |
| 2 | MAVLink2 |
| 3 | Frsky D |
| 4 | Frsky SPort |
| 5 | GPS |
| 7 | Alexmos Gimbal Serial |
| 8 | Gimbal |
| 9 | Rangefinder |
| 10 | FrSky SPort Passthrough (OpenTX) |
| 11 | Lidar360 |
| 13 | Beacon |
| 14 | Volz servo out |
| 15 | SBus servo out |
| 16 | ESC Telemetry |
| 17 | Devo Telemetry |
| 18 | OpticalFlow |
| 19 | RobotisServo |
| 20 | NMEA Output |
| 21 | WindVane |
| 22 | SLCAN |
| 23 | RCIN |
| 24 | EFI Serial |
| 25 | LTM |
| 26 | RunCam |
| 27 | HottTelem |
| 28 | Scripting |
| 29 | Crossfire VTX |
| 30 | Generator |
| 31 | Winch |
| 32 | MSP |
| 33 | DJI FPV |
| 34 | AirSpeed |
| 35 | ADSB |
| 36 | AHRS |
| 37 | SmartAudio |
| 38 | FETtecOneWire |
| 39 | Torqeedo |
| 40 | AIS |
| 41 | CoDevESC |
| 42 | DisplayPort |
| 43 | MAVLink High Latency |
| 44 | IRC Tramp |
| 45 | DDS XRCE |
| 46 | IMUDATA |
| 48 | PPP |
| 49 | i-BUS Telemetry |
| 50 | IOMCU |
Enabling this option starts selected protocol that will use this virtual driver
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | DroneCAN |
| 4 | PiccoloCAN |
| 6 | EFI_NWPMU |
| 7 | USD1 |
| 8 | KDECAN |
| 10 | Scripting |
| 11 | Benewake |
| 12 | Scripting2 |
| 13 | TOFSenseP |
| 14 | RadarCAN (NanoRadar/Hexsoon) |
Secondary protocol with 11 bit CAN addressing
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 7 | USD1 |
| 10 | Scripting |
| 11 | Benewake |
| 12 | Scripting2 |
| 13 | TOFSenseP |
| 14 | RadarCAN (NanoRadar/Hexsoon) |
Bitmask defining which ESC (motor) channels are to be transmitted over Piccolo CAN
Output rate of ESC command messages
Bitmask defining which servo channels are to be transmitted over Piccolo CAN
Output rate of servo command messages
Node ID to send ECU throttle messages to. Set to zero to disable ECU throttle messages. Set to 255 to broadcast to all ECUs.
Output rate of ECU command messages
DroneCAN node ID used by the driver itself on this network
Bitmask with one set for channel to be transmitted as a servo command over DroneCAN
Bitmask with one set for channel to be transmitted as a ESC command over DroneCAN
Maximum transmit rate for servo outputs
Option flags
Maximum transmit rate for Notify State Message
Offset for ESC numbering in DroneCAN ESC RawCommand messages. This allows for more efficient packing of ESC command messages. If your ESCs are on servo outputs 5 to 8 and you set this parameter to 4 then the ESC RawCommand will be sent with the first 4 slots filled. This can be used for more efficient usage of CAN bandwidth
Amount of memory in bytes to allocate for the DroneCAN memory pool. More memory is needed for higher CAN bus loads
Bitmask with one set for each output channel that uses a reversible ESC over DroneCAN. Reversible ESCs use both positive and negative values in RawCommands, with positive commanding the forward direction and negative commanding the reverse direction.
Maximum transmit rate for relay outputs, note that this rate is per message each message does 1 relay, so if with more relays will take longer to update at the same rate, a extra message will be sent when a relay changes state
Enable DroneCAN virtual serial ports
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
CAN remote node number for serial port
Serial port number on remote CAN node
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 0 | Serial0 |
| 1 | Serial1 |
| 2 | Serial2 |
| 3 | Serial3 |
| 4 | Serial4 |
| 5 | Serial5 |
| 6 | Serial6 |
Serial baud rate on remote CAN node
| Value | Meaning |
|---|---|
| 1 | 1200 |
| 2 | 2400 |
| 4 | 4800 |
| 9 | 9600 |
| 19 | 19200 |
| 38 | 38400 |
| 57 | 57600 |
| 111 | 111100 |
| 115 | 115200 |
| 230 | 230400 |
| 256 | 256000 |
| 460 | 460800 |
| 500 | 500000 |
| 921 | 921600 |
| 1500 | 1.5MBaud |
| 2000 | 2MBaud |
| 12500000 | 12.5MBaud |
Serial protocol of DroneCAN serial port
| Value | Meaning |
|---|---|
| -1 | None |
| 1 | MAVLink1 |
| 2 | MAVLink2 |
| 3 | Frsky D |
| 4 | Frsky SPort |
| 5 | GPS |
| 7 | Alexmos Gimbal Serial |
| 8 | Gimbal |
| 9 | Rangefinder |
| 10 | FrSky SPort Passthrough (OpenTX) |
| 11 | Lidar360 |
| 13 | Beacon |
| 14 | Volz servo out |
| 15 | SBus servo out |
| 16 | ESC Telemetry |
| 17 | Devo Telemetry |
| 18 | OpticalFlow |
| 19 | RobotisServo |
| 20 | NMEA Output |
| 21 | WindVane |
| 22 | SLCAN |
| 23 | RCIN |
| 24 | EFI Serial |
| 25 | LTM |
| 26 | RunCam |
| 27 | HottTelem |
| 28 | Scripting |
| 29 | Crossfire VTX |
| 30 | Generator |
| 31 | Winch |
| 32 | MSP |
| 33 | DJI FPV |
| 34 | AirSpeed |
| 35 | ADSB |
| 36 | AHRS |
| 37 | SmartAudio |
| 38 | FETtecOneWire |
| 39 | Torqeedo |
| 40 | AIS |
| 41 | CoDevESC |
| 42 | DisplayPort |
| 43 | MAVLink High Latency |
| 44 | IRC Tramp |
| 45 | DDS XRCE |
| 46 | IMUDATA |
| 48 | PPP |
| 49 | i-BUS Telemetry |
| 50 | IOMCU |
CAN remote node number for serial port
Serial port number on remote CAN node
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 0 | Serial0 |
| 1 | Serial1 |
| 2 | Serial2 |
| 3 | Serial3 |
| 4 | Serial4 |
| 5 | Serial5 |
| 6 | Serial6 |
Serial baud rate on remote CAN node
| Value | Meaning |
|---|---|
| 1 | 1200 |
| 2 | 2400 |
| 4 | 4800 |
| 9 | 9600 |
| 19 | 19200 |
| 38 | 38400 |
| 57 | 57600 |
| 111 | 111100 |
| 115 | 115200 |
| 230 | 230400 |
| 256 | 256000 |
| 460 | 460800 |
| 500 | 500000 |
| 921 | 921600 |
| 1500 | 1.5MBaud |
| 2000 | 2MBaud |
| 12500000 | 12.5MBaud |
Serial protocol of DroneCAN serial port
| Value | Meaning |
|---|---|
| -1 | None |
| 1 | MAVLink1 |
| 2 | MAVLink2 |
| 3 | Frsky D |
| 4 | Frsky SPort |
| 5 | GPS |
| 7 | Alexmos Gimbal Serial |
| 8 | Gimbal |
| 9 | Rangefinder |
| 10 | FrSky SPort Passthrough (OpenTX) |
| 11 | Lidar360 |
| 13 | Beacon |
| 14 | Volz servo out |
| 15 | SBus servo out |
| 16 | ESC Telemetry |
| 17 | Devo Telemetry |
| 18 | OpticalFlow |
| 19 | RobotisServo |
| 20 | NMEA Output |
| 21 | WindVane |
| 22 | SLCAN |
| 23 | RCIN |
| 24 | EFI Serial |
| 25 | LTM |
| 26 | RunCam |
| 27 | HottTelem |
| 28 | Scripting |
| 29 | Crossfire VTX |
| 30 | Generator |
| 31 | Winch |
| 32 | MSP |
| 33 | DJI FPV |
| 34 | AirSpeed |
| 35 | ADSB |
| 36 | AHRS |
| 37 | SmartAudio |
| 38 | FETtecOneWire |
| 39 | Torqeedo |
| 40 | AIS |
| 41 | CoDevESC |
| 42 | DisplayPort |
| 43 | MAVLink High Latency |
| 44 | IRC Tramp |
| 45 | DDS XRCE |
| 46 | IMUDATA |
| 48 | PPP |
| 49 | i-BUS Telemetry |
| 50 | IOMCU |
CAN node number for serial port
Serial port number on remote CAN node
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 0 | Serial0 |
| 1 | Serial1 |
| 2 | Serial2 |
| 3 | Serial3 |
| 4 | Serial4 |
| 5 | Serial5 |
| 6 | Serial6 |
Serial baud rate on remote CAN node
| Value | Meaning |
|---|---|
| 1 | 1200 |
| 2 | 2400 |
| 4 | 4800 |
| 9 | 9600 |
| 19 | 19200 |
| 38 | 38400 |
| 57 | 57600 |
| 111 | 111100 |
| 115 | 115200 |
| 230 | 230400 |
| 256 | 256000 |
| 460 | 460800 |
| 500 | 500000 |
| 921 | 921600 |
| 1500 | 1.5MBaud |
| 2000 | 2MBaud |
| 12500000 | 12.5MBaud |
Serial protocol of DroneCAN serial port
| Value | Meaning |
|---|---|
| -1 | None |
| 1 | MAVLink1 |
| 2 | MAVLink2 |
| 3 | Frsky D |
| 4 | Frsky SPort |
| 5 | GPS |
| 7 | Alexmos Gimbal Serial |
| 8 | Gimbal |
| 9 | Rangefinder |
| 10 | FrSky SPort Passthrough (OpenTX) |
| 11 | Lidar360 |
| 13 | Beacon |
| 14 | Volz servo out |
| 15 | SBus servo out |
| 16 | ESC Telemetry |
| 17 | Devo Telemetry |
| 18 | OpticalFlow |
| 19 | RobotisServo |
| 20 | NMEA Output |
| 21 | WindVane |
| 22 | SLCAN |
| 23 | RCIN |
| 24 | EFI Serial |
| 25 | LTM |
| 26 | RunCam |
| 27 | HottTelem |
| 28 | Scripting |
| 29 | Crossfire VTX |
| 30 | Generator |
| 31 | Winch |
| 32 | MSP |
| 33 | DJI FPV |
| 34 | AirSpeed |
| 35 | ADSB |
| 36 | AHRS |
| 37 | SmartAudio |
| 38 | FETtecOneWire |
| 39 | Torqeedo |
| 40 | AIS |
| 41 | CoDevESC |
| 42 | DisplayPort |
| 43 | MAVLink High Latency |
| 44 | IRC Tramp |
| 45 | DDS XRCE |
| 46 | IMUDATA |
| 48 | PPP |
| 49 | i-BUS Telemetry |
| 50 | IOMCU |
Enabling this option starts selected protocol that will use this virtual driver
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | DroneCAN |
| 4 | PiccoloCAN |
| 6 | EFI_NWPMU |
| 7 | USD1 |
| 8 | KDECAN |
| 10 | Scripting |
| 11 | Benewake |
| 12 | Scripting2 |
| 13 | TOFSenseP |
| 14 | RadarCAN (NanoRadar/Hexsoon) |
Secondary protocol with 11 bit CAN addressing
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 7 | USD1 |
| 10 | Scripting |
| 11 | Benewake |
| 12 | Scripting2 |
| 13 | TOFSenseP |
| 14 | RadarCAN (NanoRadar/Hexsoon) |
Bitmask defining which ESC (motor) channels are to be transmitted over Piccolo CAN
Output rate of ESC command messages
Bitmask defining which servo channels are to be transmitted over Piccolo CAN
Output rate of servo command messages
Node ID to send ECU throttle messages to. Set to zero to disable ECU throttle messages. Set to 255 to broadcast to all ECUs.
Output rate of ECU command messages
DroneCAN node ID used by the driver itself on this network
Bitmask with one set for channel to be transmitted as a servo command over DroneCAN
Bitmask with one set for channel to be transmitted as a ESC command over DroneCAN
Maximum transmit rate for servo outputs
Option flags
Maximum transmit rate for Notify State Message
Offset for ESC numbering in DroneCAN ESC RawCommand messages. This allows for more efficient packing of ESC command messages. If your ESCs are on servo outputs 5 to 8 and you set this parameter to 4 then the ESC RawCommand will be sent with the first 4 slots filled. This can be used for more efficient usage of CAN bandwidth
Amount of memory in bytes to allocate for the DroneCAN memory pool. More memory is needed for higher CAN bus loads
Bitmask with one set for each output channel that uses a reversible ESC over DroneCAN. Reversible ESCs use both positive and negative values in RawCommands, with positive commanding the forward direction and negative commanding the reverse direction.
Maximum transmit rate for relay outputs, note that this rate is per message each message does 1 relay, so if with more relays will take longer to update at the same rate, a extra message will be sent when a relay changes state
Enable DroneCAN virtual serial ports
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
CAN remote node number for serial port
Serial port number on remote CAN node
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 0 | Serial0 |
| 1 | Serial1 |
| 2 | Serial2 |
| 3 | Serial3 |
| 4 | Serial4 |
| 5 | Serial5 |
| 6 | Serial6 |
Serial baud rate on remote CAN node
| Value | Meaning |
|---|---|
| 1 | 1200 |
| 2 | 2400 |
| 4 | 4800 |
| 9 | 9600 |
| 19 | 19200 |
| 38 | 38400 |
| 57 | 57600 |
| 111 | 111100 |
| 115 | 115200 |
| 230 | 230400 |
| 256 | 256000 |
| 460 | 460800 |
| 500 | 500000 |
| 921 | 921600 |
| 1500 | 1.5MBaud |
| 2000 | 2MBaud |
| 12500000 | 12.5MBaud |
Serial protocol of DroneCAN serial port
| Value | Meaning |
|---|---|
| -1 | None |
| 1 | MAVLink1 |
| 2 | MAVLink2 |
| 3 | Frsky D |
| 4 | Frsky SPort |
| 5 | GPS |
| 7 | Alexmos Gimbal Serial |
| 8 | Gimbal |
| 9 | Rangefinder |
| 10 | FrSky SPort Passthrough (OpenTX) |
| 11 | Lidar360 |
| 13 | Beacon |
| 14 | Volz servo out |
| 15 | SBus servo out |
| 16 | ESC Telemetry |
| 17 | Devo Telemetry |
| 18 | OpticalFlow |
| 19 | RobotisServo |
| 20 | NMEA Output |
| 21 | WindVane |
| 22 | SLCAN |
| 23 | RCIN |
| 24 | EFI Serial |
| 25 | LTM |
| 26 | RunCam |
| 27 | HottTelem |
| 28 | Scripting |
| 29 | Crossfire VTX |
| 30 | Generator |
| 31 | Winch |
| 32 | MSP |
| 33 | DJI FPV |
| 34 | AirSpeed |
| 35 | ADSB |
| 36 | AHRS |
| 37 | SmartAudio |
| 38 | FETtecOneWire |
| 39 | Torqeedo |
| 40 | AIS |
| 41 | CoDevESC |
| 42 | DisplayPort |
| 43 | MAVLink High Latency |
| 44 | IRC Tramp |
| 45 | DDS XRCE |
| 46 | IMUDATA |
| 48 | PPP |
| 49 | i-BUS Telemetry |
| 50 | IOMCU |
CAN remote node number for serial port
Serial port number on remote CAN node
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 0 | Serial0 |
| 1 | Serial1 |
| 2 | Serial2 |
| 3 | Serial3 |
| 4 | Serial4 |
| 5 | Serial5 |
| 6 | Serial6 |
Serial baud rate on remote CAN node
| Value | Meaning |
|---|---|
| 1 | 1200 |
| 2 | 2400 |
| 4 | 4800 |
| 9 | 9600 |
| 19 | 19200 |
| 38 | 38400 |
| 57 | 57600 |
| 111 | 111100 |
| 115 | 115200 |
| 230 | 230400 |
| 256 | 256000 |
| 460 | 460800 |
| 500 | 500000 |
| 921 | 921600 |
| 1500 | 1.5MBaud |
| 2000 | 2MBaud |
| 12500000 | 12.5MBaud |
Serial protocol of DroneCAN serial port
| Value | Meaning |
|---|---|
| -1 | None |
| 1 | MAVLink1 |
| 2 | MAVLink2 |
| 3 | Frsky D |
| 4 | Frsky SPort |
| 5 | GPS |
| 7 | Alexmos Gimbal Serial |
| 8 | Gimbal |
| 9 | Rangefinder |
| 10 | FrSky SPort Passthrough (OpenTX) |
| 11 | Lidar360 |
| 13 | Beacon |
| 14 | Volz servo out |
| 15 | SBus servo out |
| 16 | ESC Telemetry |
| 17 | Devo Telemetry |
| 18 | OpticalFlow |
| 19 | RobotisServo |
| 20 | NMEA Output |
| 21 | WindVane |
| 22 | SLCAN |
| 23 | RCIN |
| 24 | EFI Serial |
| 25 | LTM |
| 26 | RunCam |
| 27 | HottTelem |
| 28 | Scripting |
| 29 | Crossfire VTX |
| 30 | Generator |
| 31 | Winch |
| 32 | MSP |
| 33 | DJI FPV |
| 34 | AirSpeed |
| 35 | ADSB |
| 36 | AHRS |
| 37 | SmartAudio |
| 38 | FETtecOneWire |
| 39 | Torqeedo |
| 40 | AIS |
| 41 | CoDevESC |
| 42 | DisplayPort |
| 43 | MAVLink High Latency |
| 44 | IRC Tramp |
| 45 | DDS XRCE |
| 46 | IMUDATA |
| 48 | PPP |
| 49 | i-BUS Telemetry |
| 50 | IOMCU |
CAN node number for serial port
Serial port number on remote CAN node
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 0 | Serial0 |
| 1 | Serial1 |
| 2 | Serial2 |
| 3 | Serial3 |
| 4 | Serial4 |
| 5 | Serial5 |
| 6 | Serial6 |
Serial baud rate on remote CAN node
| Value | Meaning |
|---|---|
| 1 | 1200 |
| 2 | 2400 |
| 4 | 4800 |
| 9 | 9600 |
| 19 | 19200 |
| 38 | 38400 |
| 57 | 57600 |
| 111 | 111100 |
| 115 | 115200 |
| 230 | 230400 |
| 256 | 256000 |
| 460 | 460800 |
| 500 | 500000 |
| 921 | 921600 |
| 1500 | 1.5MBaud |
| 2000 | 2MBaud |
| 12500000 | 12.5MBaud |
Serial protocol of DroneCAN serial port
| Value | Meaning |
|---|---|
| -1 | None |
| 1 | MAVLink1 |
| 2 | MAVLink2 |
| 3 | Frsky D |
| 4 | Frsky SPort |
| 5 | GPS |
| 7 | Alexmos Gimbal Serial |
| 8 | Gimbal |
| 9 | Rangefinder |
| 10 | FrSky SPort Passthrough (OpenTX) |
| 11 | Lidar360 |
| 13 | Beacon |
| 14 | Volz servo out |
| 15 | SBus servo out |
| 16 | ESC Telemetry |
| 17 | Devo Telemetry |
| 18 | OpticalFlow |
| 19 | RobotisServo |
| 20 | NMEA Output |
| 21 | WindVane |
| 22 | SLCAN |
| 23 | RCIN |
| 24 | EFI Serial |
| 25 | LTM |
| 26 | RunCam |
| 27 | HottTelem |
| 28 | Scripting |
| 29 | Crossfire VTX |
| 30 | Generator |
| 31 | Winch |
| 32 | MSP |
| 33 | DJI FPV |
| 34 | AirSpeed |
| 35 | ADSB |
| 36 | AHRS |
| 37 | SmartAudio |
| 38 | FETtecOneWire |
| 39 | Torqeedo |
| 40 | AIS |
| 41 | CoDevESC |
| 42 | DisplayPort |
| 43 | MAVLink High Latency |
| 44 | IRC Tramp |
| 45 | DDS XRCE |
| 46 | IMUDATA |
| 48 | PPP |
| 49 | i-BUS Telemetry |
| 50 | IOMCU |
Enabling this option enables use of CAN buses.
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | First driver |
| 2 | Second driver |
| 3 | Third driver |
Bit rate can be set up to from 10000 to 1000000
Bit rate can be set up to from 1000000 to 8000000
| Value | Meaning |
|---|---|
| 1 | 1M |
| 2 | 2M |
| 4 | 4M |
| 5 | 5M |
| 8 | 8M |
CAN per-interface options
Enabling this option enables use of CAN buses.
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | First driver |
| 2 | Second driver |
| 3 | Third driver |
Bit rate can be set up to from 10000 to 1000000
Bit rate can be set up to from 1000000 to 8000000
| Value | Meaning |
|---|---|
| 1 | 1M |
| 2 | 2M |
| 4 | 4M |
| 5 | 5M |
| 8 | 8M |
CAN per-interface options
Enabling this option enables use of CAN buses.
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | First driver |
| 2 | Second driver |
| 3 | Third driver |
Bit rate can be set up to from 10000 to 1000000
Bit rate can be set up to from 1000000 to 8000000
| Value | Meaning |
|---|---|
| 1 | 1M |
| 2 | 2M |
| 4 | 4M |
| 5 | 5M |
| 8 | 8M |
CAN per-interface options
CAN Interface ID to be routed to SLCAN, 0 means no routing
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | First interface |
| 2 | Second interface |
Serial Port ID to be used for temporary SLCAN iface, -1 means no temporary serial. This parameter is automatically reset on reboot or on timeout. See CAN_SLCAN_TIMOUT for timeout details
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 0 | Serial0 |
| 1 | Serial1 |
| 2 | Serial2 |
| 3 | Serial3 |
| 4 | Serial4 |
| 5 | Serial5 |
| 6 | Serial6 |
Duration of inactivity after which SLCAN is switched back to original driver in seconds.
Duration after which slcan starts after setting SERNUM in seconds.
Offset to be added to the compass x-axis values to compensate for metal in the frame
Offset to be added to the compass y-axis values to compensate for metal in the frame
Offset to be added to the compass z-axis values to compensate for metal in the frame
An angle to compensate between the true north and magnetic north
Enable or disable the automatic learning of compass offsets. You can enable learning either using a compass-only method that is suitable only for fixed wing aircraft or using the offsets learnt by the active EKF state estimator. If this option is enabled then the learnt offsets are saved when you disarm the vehicle. If InFlight learning is enabled then the compass with automatically start learning once a flight starts (must be armed). While InFlight learning is running you cannot use position control modes.
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 2 | EKF-Learning |
| 3 | InFlight-Learning |
Enable or disable the use of the compass (instead of the GPS) for determining heading
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
Enable or disable the automatic calculation of the declination based on gps location
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
Set motor interference compensation type to disabled, throttle or current. Do not change manually.
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Use Throttle |
| 2 | Use Current |
Multiplied by the current throttle and added to the compass's x-axis values to compensate for motor interference (Offset per Amp or at Full Throttle)
Multiplied by the current throttle and added to the compass's y-axis values to compensate for motor interference (Offset per Amp or at Full Throttle)
Multiplied by the current throttle and added to the compass's z-axis values to compensate for motor interference (Offset per Amp or at Full Throttle)
The orientation of the first external compass relative to the vehicle frame. This value will be ignored unless this compass is set as an external compass. When set correctly in the northern hemisphere, pointing the nose and right side down should increase the MagX and MagY values respectively. Rolling the vehicle upside down should decrease the MagZ value. For southern hemisphere, switch increase and decrease. NOTE: For internal compasses, AHRS_ORIENT is used. The label for each option is specified in the order of rotations for that orientation. Firmware versions 4.2 and prior can use a CUSTOM (100) rotation to set the COMPASS_CUS_ROLL/PIT/YAW angles for Compass orientation. Later versions provide two general custom rotations which can be used, Custom 1 and Custom 2, with CUST_1_ROLL/PIT/YAW or CUST_2_ROLL/PIT/YAW angles.
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Yaw45 |
| 2 | Yaw90 |
| 3 | Yaw135 |
| 4 | Yaw180 |
| 5 | Yaw225 |
| 6 | Yaw270 |
| 7 | Yaw315 |
| 8 | Roll180 |
| 9 | Yaw45Roll180 |
| 10 | Yaw90Roll180 |
| 11 | Yaw135Roll180 |
| 12 | Pitch180 |
| 13 | Yaw225Roll180 |
| 14 | Yaw270Roll180 |
| 15 | Yaw315Roll180 |
| 16 | Roll90 |
| 17 | Yaw45Roll90 |
| 18 | Yaw90Roll90 |
| 19 | Yaw135Roll90 |
| 20 | Roll270 |
| 21 | Yaw45Roll270 |
| 22 | Yaw90Roll270 |
| 23 | Yaw135Roll270 |
| 24 | Pitch90 |
| 25 | Pitch270 |
| 26 | Yaw90Pitch180 |
| 27 | Yaw270Pitch180 |
| 28 | Pitch90Roll90 |
| 29 | Pitch90Roll180 |
| 30 | Pitch90Roll270 |
| 31 | Pitch180Roll90 |
| 32 | Pitch180Roll270 |
| 33 | Pitch270Roll90 |
| 34 | Pitch270Roll180 |
| 35 | Pitch270Roll270 |
| 36 | Yaw90Pitch180Roll90 |
| 37 | Yaw270Roll90 |
| 38 | Yaw293Pitch68Roll180 |
| 39 | Pitch315 |
| 40 | Pitch315Roll90 |
| 42 | Roll45 |
| 43 | Roll315 |
| 100 | Custom 4.1 and older |
| 101 | Custom 1 |
| 102 | Custom 2 |
Configure compass so it is attached externally. This is auto-detected on most boards. Set to 1 if the compass is externally connected. When externally connected the COMPASS_ORIENT option operates independently of the AHRS_ORIENTATION board orientation option. If set to 0 or 1 then auto-detection by bus connection can override the value. If set to 2 then auto-detection will be disabled.
| Value | Meaning |
|---|---|
| 0 | Internal |
| 1 | External |
| 2 | ForcedExternal |
Offset to be added to compass2's x-axis values to compensate for metal in the frame
Offset to be added to compass2's y-axis values to compensate for metal in the frame
Offset to be added to compass2's z-axis values to compensate for metal in the frame
Multiplied by the current throttle and added to compass2's x-axis values to compensate for motor interference (Offset per Amp or at Full Throttle)
Multiplied by the current throttle and added to compass2's y-axis values to compensate for motor interference (Offset per Amp or at Full Throttle)
Multiplied by the current throttle and added to compass2's z-axis values to compensate for motor interference (Offset per Amp or at Full Throttle)
Offset to be added to compass3's x-axis values to compensate for metal in the frame
Offset to be added to compass3's y-axis values to compensate for metal in the frame
Offset to be added to compass3's z-axis values to compensate for metal in the frame
Multiplied by the current throttle and added to compass3's x-axis values to compensate for motor interference (Offset per Amp or at Full Throttle)
Multiplied by the current throttle and added to compass3's y-axis values to compensate for motor interference (Offset per Amp or at Full Throttle)
Multiplied by the current throttle and added to compass3's z-axis values to compensate for motor interference (Offset per Amp or at Full Throttle)
Compass device id. Automatically detected, do not set manually
Second compass's device id. Automatically detected, do not set manually
Third compass's device id. Automatically detected, do not set manually
Enable or disable the secondary compass for determining heading.
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
The orientation of a second external compass relative to the vehicle frame. This value will be ignored unless this compass is set as an external compass. When set correctly in the northern hemisphere, pointing the nose and right side down should increase the MagX and MagY values respectively. Rolling the vehicle upside down should decrease the MagZ value. For southern hemisphere, switch increase and decrease. NOTE: For internal compasses, AHRS_ORIENT is used. The label for each option is specified in the order of rotations for that orientation. Firmware versions 4.2 and prior can use a CUSTOM (100) rotation to set the COMPASS_CUS_ROLL/PIT/YAW angles for Compass orientation. Later versions provide two general custom rotations which can be used, Custom 1 and Custom 2, with CUST_1_ROLL/PIT/YAW or CUST_2_ROLL/PIT/YAW angles.
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Yaw45 |
| 2 | Yaw90 |
| 3 | Yaw135 |
| 4 | Yaw180 |
| 5 | Yaw225 |
| 6 | Yaw270 |
| 7 | Yaw315 |
| 8 | Roll180 |
| 9 | Yaw45Roll180 |
| 10 | Yaw90Roll180 |
| 11 | Yaw135Roll180 |
| 12 | Pitch180 |
| 13 | Yaw225Roll180 |
| 14 | Yaw270Roll180 |
| 15 | Yaw315Roll180 |
| 16 | Roll90 |
| 17 | Yaw45Roll90 |
| 18 | Yaw90Roll90 |
| 19 | Yaw135Roll90 |
| 20 | Roll270 |
| 21 | Yaw45Roll270 |
| 22 | Yaw90Roll270 |
| 23 | Yaw135Roll270 |
| 24 | Pitch90 |
| 25 | Pitch270 |
| 26 | Yaw90Pitch180 |
| 27 | Yaw270Pitch180 |
| 28 | Pitch90Roll90 |
| 29 | Pitch90Roll180 |
| 30 | Pitch90Roll270 |
| 31 | Pitch180Roll90 |
| 32 | Pitch180Roll270 |
| 33 | Pitch270Roll90 |
| 34 | Pitch270Roll180 |
| 35 | Pitch270Roll270 |
| 36 | Yaw90Pitch180Roll90 |
| 37 | Yaw270Roll90 |
| 38 | Yaw293Pitch68Roll180 |
| 39 | Pitch315 |
| 40 | Pitch315Roll90 |
| 42 | Roll45 |
| 43 | Roll315 |
| 100 | Custom 4.1 and older |
| 101 | Custom 1 |
| 102 | Custom 2 |
Configure second compass so it is attached externally. This is auto-detected on most boards. If set to 0 or 1 then auto-detection by bus connection can override the value. If set to 2 then auto-detection will be disabled.
| Value | Meaning |
|---|---|
| 0 | Internal |
| 1 | External |
| 2 | ForcedExternal |
Enable or disable the tertiary compass for determining heading.
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
The orientation of a third external compass relative to the vehicle frame. This value will be ignored unless this compass is set as an external compass. When set correctly in the northern hemisphere, pointing the nose and right side down should increase the MagX and MagY values respectively. Rolling the vehicle upside down should decrease the MagZ value. For southern hemisphere, switch increase and decrease. NOTE: For internal compasses, AHRS_ORIENT is used. The label for each option is specified in the order of rotations for that orientation. Firmware versions 4.2 and prior can use a CUSTOM (100) rotation to set the COMPASS_CUS_ROLL/PIT/YAW angles for Compass orientation. Later versions provide two general custom rotations which can be used, Custom 1 and Custom 2, with CUST_1_ROLL/PIT/YAW or CUST_2_ROLL/PIT/YAW angles.
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Yaw45 |
| 2 | Yaw90 |
| 3 | Yaw135 |
| 4 | Yaw180 |
| 5 | Yaw225 |
| 6 | Yaw270 |
| 7 | Yaw315 |
| 8 | Roll180 |
| 9 | Yaw45Roll180 |
| 10 | Yaw90Roll180 |
| 11 | Yaw135Roll180 |
| 12 | Pitch180 |
| 13 | Yaw225Roll180 |
| 14 | Yaw270Roll180 |
| 15 | Yaw315Roll180 |
| 16 | Roll90 |
| 17 | Yaw45Roll90 |
| 18 | Yaw90Roll90 |
| 19 | Yaw135Roll90 |
| 20 | Roll270 |
| 21 | Yaw45Roll270 |
| 22 | Yaw90Roll270 |
| 23 | Yaw135Roll270 |
| 24 | Pitch90 |
| 25 | Pitch270 |
| 26 | Yaw90Pitch180 |
| 27 | Yaw270Pitch180 |
| 28 | Pitch90Roll90 |
| 29 | Pitch90Roll180 |
| 30 | Pitch90Roll270 |
| 31 | Pitch180Roll90 |
| 32 | Pitch180Roll270 |
| 33 | Pitch270Roll90 |
| 34 | Pitch270Roll180 |
| 35 | Pitch270Roll270 |
| 36 | Yaw90Pitch180Roll90 |
| 37 | Yaw270Roll90 |
| 38 | Yaw293Pitch68Roll180 |
| 39 | Pitch315 |
| 40 | Pitch315Roll90 |
| 42 | Roll45 |
| 43 | Roll315 |
| 100 | Custom 4.1 and older |
| 101 | Custom 1 |
| 102 | Custom 2 |
Configure third compass so it is attached externally. This is auto-detected on most boards. If set to 0 or 1 then auto-detection by bus connection can override the value. If set to 2 then auto-detection will be disabled.
| Value | Meaning |
|---|---|
| 0 | Internal |
| 1 | External |
| 2 | ForcedExternal |
DIA_X in the compass soft-iron calibration matrix: [[DIA_X, ODI_X, ODI_Y], [ODI_X, DIA_Y, ODI_Z], [ODI_Y, ODI_Z, DIA_Z]]
DIA_Y in the compass soft-iron calibration matrix: [[DIA_X, ODI_X, ODI_Y], [ODI_X, DIA_Y, ODI_Z], [ODI_Y, ODI_Z, DIA_Z]]
DIA_Z in the compass soft-iron calibration matrix: [[DIA_X, ODI_X, ODI_Y], [ODI_X, DIA_Y, ODI_Z], [ODI_Y, ODI_Z, DIA_Z]]
ODI_X in the compass soft-iron calibration matrix: [[DIA_X, ODI_X, ODI_Y], [ODI_X, DIA_Y, ODI_Z], [ODI_Y, ODI_Z, DIA_Z]]
ODI_Y in the compass soft-iron calibration matrix: [[DIA_X, ODI_X, ODI_Y], [ODI_X, DIA_Y, ODI_Z], [ODI_Y, ODI_Z, DIA_Z]]
ODI_Z in the compass soft-iron calibration matrix: [[DIA_X, ODI_X, ODI_Y], [ODI_X, DIA_Y, ODI_Z], [ODI_Y, ODI_Z, DIA_Z]]
DIA_X in the compass2 soft-iron calibration matrix: [[DIA_X, ODI_X, ODI_Y], [ODI_X, DIA_Y, ODI_Z], [ODI_Y, ODI_Z, DIA_Z]]
DIA_Y in the compass2 soft-iron calibration matrix: [[DIA_X, ODI_X, ODI_Y], [ODI_X, DIA_Y, ODI_Z], [ODI_Y, ODI_Z, DIA_Z]]
DIA_Z in the compass2 soft-iron calibration matrix: [[DIA_X, ODI_X, ODI_Y], [ODI_X, DIA_Y, ODI_Z], [ODI_Y, ODI_Z, DIA_Z]]
ODI_X in the compass2 soft-iron calibration matrix: [[DIA_X, ODI_X, ODI_Y], [ODI_X, DIA_Y, ODI_Z], [ODI_Y, ODI_Z, DIA_Z]]
ODI_Y in the compass2 soft-iron calibration matrix: [[DIA_X, ODI_X, ODI_Y], [ODI_X, DIA_Y, ODI_Z], [ODI_Y, ODI_Z, DIA_Z]]
ODI_Z in the compass2 soft-iron calibration matrix: [[DIA_X, ODI_X, ODI_Y], [ODI_X, DIA_Y, ODI_Z], [ODI_Y, ODI_Z, DIA_Z]]
DIA_X in the compass3 soft-iron calibration matrix: [[DIA_X, ODI_X, ODI_Y], [ODI_X, DIA_Y, ODI_Z], [ODI_Y, ODI_Z, DIA_Z]]
DIA_Y in the compass3 soft-iron calibration matrix: [[DIA_X, ODI_X, ODI_Y], [ODI_X, DIA_Y, ODI_Z], [ODI_Y, ODI_Z, DIA_Z]]
DIA_Z in the compass3 soft-iron calibration matrix: [[DIA_X, ODI_X, ODI_Y], [ODI_X, DIA_Y, ODI_Z], [ODI_Y, ODI_Z, DIA_Z]]
ODI_X in the compass3 soft-iron calibration matrix: [[DIA_X, ODI_X, ODI_Y], [ODI_X, DIA_Y, ODI_Z], [ODI_Y, ODI_Z, DIA_Z]]
ODI_Y in the compass3 soft-iron calibration matrix: [[DIA_X, ODI_X, ODI_Y], [ODI_X, DIA_Y, ODI_Z], [ODI_Y, ODI_Z, DIA_Z]]
ODI_Z in the compass3 soft-iron calibration matrix: [[DIA_X, ODI_X, ODI_Y], [ODI_X, DIA_Y, ODI_Z], [ODI_Y, ODI_Z, DIA_Z]]
This controls the fitness level required for a successful compass calibration. A lower value makes for a stricter fit (less likely to pass). This is the value used for the primary magnetometer. Other magnetometers get double the value.
| Value | Meaning |
|---|---|
| 4 | Very Strict |
| 8 | Strict |
| 16 | Default |
| 32 | Relaxed |
This sets the maximum allowed compass offset in calibration and arming checks
This is a bitmask of driver types to disable. If a driver type is set in this mask then that driver will not try to find a sensor at startup
This sets the range around the average value that new samples must be within to be accepted. This can help reduce the impact of noise on sensors that are on long I2C cables. The value is a percentage from the average value. A value of zero disables this filter.
When enabled this will automatically check the orientation of compasses on successful completion of compass calibration. If set to 2 then external compasses will have their orientation automatically corrected.
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | CheckOnly |
| 2 | CheckAndFix |
| 3 | use same tolerance to auto rotate 45 deg rotations |
Compass device id with 1st order priority, set automatically if 0. Reboot required after change.
Compass device id with 2nd order priority, set automatically if 0. Reboot required after change.
Compass device id with 3rd order priority, set automatically if 0. Reboot required after change.
Setting this to Enabled(1) will enable the compass. Setting this to Disabled(0) will disable the compass. Note that this is separate from COMPASS_USE. This will enable the low level senor, and will enable logging of magnetometer data. To use the compass for navigation you must also set COMPASS_USE to 1.
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
Scaling factor for first compass to compensate for sensor scaling errors. If this is 0 then no scaling is done
Scaling factor for 2nd compass to compensate for sensor scaling errors. If this is 0 then no scaling is done
Scaling factor for 3rd compass to compensate for sensor scaling errors. If this is 0 then no scaling is done
This sets options to change the behaviour of the compass
Extra 4th compass's device id. Automatically detected, do not set manually
Extra 5th compass's device id. Automatically detected, do not set manually
Extra 6th compass's device id. Automatically detected, do not set manually
Extra 7th compass's device id. Automatically detected, do not set manually
Extra 8th compass's device id. Automatically detected, do not set manually
Compass mounting position roll offset. Positive values = roll right, negative values = roll left. This parameter is only used when COMPASS_ORIENT/2/3 is set to CUSTOM.
Compass mounting position pitch offset. Positive values = pitch up, negative values = pitch down. This parameter is only used when COMPASS_ORIENT/2/3 is set to CUSTOM.
Compass mounting position yaw offset. Positive values = yaw right, negative values = yaw left. This parameter is only used when COMPASS_ORIENT/2/3 is set to CUSTOM.
This enables per-motor compass corrections
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
This is the exponential correction for the power output of the motor for per-motor compass correction
Compensation for X axis of motor1
Compensation for Y axis of motor1
Compensation for Z axis of motor1
Compensation for X axis of motor2
Compensation for Y axis of motor2
Compensation for Z axis of motor2
Compensation for X axis of motor3
Compensation for Y axis of motor3
Compensation for Z axis of motor3
Compensation for X axis of motor4
Compensation for Y axis of motor4
Compensation for Z axis of motor4
This enables custom rotations
| Value | Meaning |
|---|---|
| 0 | Disable |
| 1 | Enable |
Custom euler roll, euler 321 (yaw, pitch, roll) ordering
Custom euler pitch, euler 321 (yaw, pitch, roll) ordering
Custom euler yaw, euler 321 (yaw, pitch, roll) ordering
Custom euler roll, euler 321 (yaw, pitch, roll) ordering
Custom euler pitch, euler 321 (yaw, pitch, roll) ordering
Custom euler yaw, euler 321 (yaw, pitch, roll) ordering
Enable DDS subsystem
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
UDP port number for DDS
Set the ROS_DOMAIN_ID
The time in milliseconds the DDS client will wait for a response from the XRCE agent before reattempting.
The maximum number of times the DDS client will attempt to ping the XRCE agent before exiting. Set to 0 to allow unlimited retries.
IPv4 address. Example: 192.xxx.xxx.xxx
IPv4 address. Example: xxx.168.xxx.xxx
IPv4 address. Example: xxx.xxx.144.xxx
IPv4 address. Example: xxx.xxx.xxx.14
Enable ODID subsystem
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
Serial port number to send OpenDroneID MAVLink messages to. Can be -1 if using DroneCAN.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 0 | Serial0 |
| 1 | Serial1 |
| 2 | Serial2 |
| 3 | Serial3 |
| 4 | Serial4 |
| 5 | Serial5 |
| 6 | Serial6 |
DroneCAN driver index, 0 to disable DroneCAN
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Driver1 |
| 2 | Driver2 |
Options for OpenDroneID subsystem
Barometer Vertical Accuracy when installed in the vehicle. Note this is dependent upon installation conditions and thus disabled by default
Type of AHRS device
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | VectorNav |
| 2 | MicroStrain5 |
| 5 | InertialLabs |
| 7 | MicroStrain7 |
| 8 | SBG |
Requested rate for AHRS device
External AHRS options bitmask
External AHRS sensors bitmask
Logging rate for EARHS devices
What method of communication is used for EFI #1
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Serial-MS |
| 2 | NWPMU |
| 3 | Serial-Lutan |
| 4 | Loweheiser |
| 5 | DroneCAN |
| 6 | Currawong-ECU |
| 7 | Scripting |
| 8 | Hirth |
| 9 | MAVLink |
Used to calibrate fuel flow for MS protocol (Slope). This should be calculated from a log at constant fuel usage rate. Plot (ECYL[0].InjT*EFI.Rpm)/600.0 to get the duty_cycle. Measure actual fuel usage in cm^3/min, and set EFI_COEF1 = fuel_usage_cm3permin / duty_cycle
Used to calibrate fuel flow for MS protocol (Offset). This can be used to correct for a non-zero offset in the fuel consumption calculation of EFI_COEF1
Used to calculate fuel consumption
Enable EFI throttle linearisation
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
First Order Polynomial Coefficient. (=1, if throttle is first order polynomial trendline)
Second Order Polynomial Coefficient (=0, if throttle is second order polynomial trendline)
Third Order Polynomial Coefficient. (=0, if throttle is third order polynomial trendline)
Offset for throttle linearization
This enables EKF2. Enabling EKF2 only makes the maths run, it does not mean it will be used for flight control. To use it for flight control set AHRS_EKF_TYPE=2. A reboot or restart will need to be performed after changing the value of EK2_ENABLE for it to take effect.
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
This controls use of GPS measurements : 0 = use 3D velocity & 2D position, 1 = use 2D velocity and 2D position, 2 = use 2D position, 3 = Inhibit GPS use - this can be useful when flying with an optical flow sensor in an environment where GPS quality is poor and subject to large multipath errors.
| Value | Meaning |
|---|---|
| 0 | GPS 3D Vel and 2D Pos |
| 1 | GPS 2D vel and 2D pos |
| 2 | GPS 2D pos |
| 3 | No GPS |
This sets a lower limit on the speed accuracy reported by the GPS receiver that is used to set horizontal velocity observation noise. If the model of receiver used does not provide a speed accurcy estimate, then the parameter value will be used. Increasing it reduces the weighting of the GPS horizontal velocity measurements.
This sets a lower limit on the speed accuracy reported by the GPS receiver that is used to set vertical velocity observation noise. If the model of receiver used does not provide a speed accurcy estimate, then the parameter value will be used. Increasing it reduces the weighting of the GPS vertical velocity measurements.
This sets the percentage number of standard deviations applied to the GPS velocity measurement innovation consistency check. Decreasing it makes it more likely that good measurements will be rejected. Increasing it makes it more likely that bad measurements will be accepted.
This sets the GPS horizontal position observation noise. Increasing it reduces the weighting of GPS horizontal position measurements.
This sets the percentage number of standard deviations applied to the GPS position measurement innovation consistency check. Decreasing it makes it more likely that good measurements will be rejected. Increasing it makes it more likely that bad measurements will be accepted.
This controls the maximum radial uncertainty in position between the value predicted by the filter and the value measured by the GPS before the filter position and velocity states are reset to the GPS. Making this value larger allows the filter to ignore larger GPS glitches but also means that non-GPS errors such as IMU and compass can create a larger error in position before the filter is forced back to the GPS position.
Primary height sensor used by the EKF. If a sensor other than Baro is selected and becomes unavailable, then the Baro sensor will be used as a fallback. NOTE: The EK2_RNG_USE_HGT parameter can be used to switch to range-finder when close to the ground in conjunction with EK2_ALT_SOURCE = 0 or 2 (Baro or GPS).
| Value | Meaning |
|---|---|
| 0 | Use Baro |
| 1 | Use Range Finder |
| 2 | Use GPS |
| 3 | Use Range Beacon |
This is the RMS value of noise in the altitude measurement. Increasing it reduces the weighting of the baro measurement and will make the filter respond more slowly to baro measurement errors, but will make it more sensitive to GPS and accelerometer errors.
This sets the percentage number of standard deviations applied to the height measurement innovation consistency check. Decreasing it makes it more likely that good measurements will be rejected. Increasing it makes it more likely that bad measurements will be accepted.
This is the number of msec that the Height measurements lag behind the inertial measurements.
This is the RMS value of noise in magnetometer measurements. Increasing it reduces the weighting on these measurements.
This determines when the filter will use the 3-axis magnetometer fusion model that estimates both earth and body fixed magnetic field states, when it will use a simpler magnetic heading fusion model that does not use magnetic field states and when it will use an alternative method of yaw determination to the magnetometer. The 3-axis magnetometer fusion is only suitable for use when the external magnetic field environment is stable. EK2_MAG_CAL = 0 uses heading fusion on ground, 3-axis fusion in-flight, and is the default setting for Plane users. EK2_MAG_CAL = 1 uses 3-axis fusion only when manoeuvring. EK2_MAG_CAL = 2 uses heading fusion at all times, is recommended if the external magnetic field is varying and is the default for rovers. EK2_MAG_CAL = 3 uses heading fusion on the ground and 3-axis fusion after the first in-air field and yaw reset has completed, and is the default for copters. EK2_MAG_CAL = 4 uses 3-axis fusion at all times. NOTE: The fusion mode can be forced to 2 for specific EKF cores using the EK2_MAG_MASK parameter. NOTE: limited operation without a magnetometer or any other yaw sensor is possible by setting all COMPASS_USE, COMPASS_USE2, COMPASS_USE3, etc parameters to 0 with COMPASS_ENABLE set to 1. If this is done, the EK2_GSF_RUN and EK2_GSF_USE masks must be set to the same as EK2_IMU_MASK.
| Value | Meaning |
|---|---|
| 0 | When flying |
| 1 | When manoeuvring |
| 2 | Never |
| 3 | After first climb yaw reset |
| 4 | Always |
This sets the percentage number of standard deviations applied to the magnetometer measurement innovation consistency check. Decreasing it makes it more likely that good measurements will be rejected. Increasing it makes it more likely that bad measurements will be accepted.
This is the RMS value of noise in equivalent airspeed measurements used by planes. Increasing it reduces the weighting of airspeed measurements and will make wind speed estimates less noisy and slower to converge. Increasing also increases navigation errors when dead-reckoning without GPS measurements.
This sets the percentage number of standard deviations applied to the airspeed measurement innovation consistency check. Decreasing it makes it more likely that good measurements will be rejected. Increasing it makes it more likely that bad measurements will be accepted.
This is the RMS value of noise in the range finder measurement. Increasing it reduces the weighting on this measurement.
This sets the percentage number of standard deviations applied to the range finder innovation consistency check. Decreasing it makes it more likely that good measurements will be rejected. Increasing it makes it more likely that bad measurements will be accepted.
This sets the magnitude maximum optical flow rate in rad/sec that will be accepted by the filter
This is the RMS value of noise and errors in optical flow measurements. Increasing it reduces the weighting on these measurements.
This sets the percentage number of standard deviations applied to the optical flow innovation consistency check. Decreasing it makes it more likely that good measurements will be rejected. Increasing it makes it more likely that bad measurements will be accepted.
This is the number of msec that the optical flow measurements lag behind the inertial measurements. It is the time from the end of the optical flow averaging period and does not include the time delay due to the 100msec of averaging within the flow sensor.
This control disturbance noise controls the growth of estimated error due to gyro measurement errors excluding bias. Increasing it makes the flter trust the gyro measurements less and other measurements more.
This control disturbance noise controls the growth of estimated error due to accelerometer measurement errors excluding bias. Increasing it makes the flter trust the accelerometer measurements less and other measurements more.
This state process noise controls growth of the gyro delta angle bias state error estimate. Increasing it makes rate gyro bias estimation faster and noisier.
This noise controls the rate of gyro scale factor learning. Increasing it makes rate gyro scale factor estimation faster and noisier.
This noise controls the growth of the vertical accelerometer delta velocity bias state error estimate. Increasing it makes accelerometer bias estimation faster and noisier.
This state process noise controls the growth of wind state error estimates. Increasing it makes wind estimation faster and noisier.
This controls how much the process noise on the wind states is increased when gaining or losing altitude to take into account changes in wind speed and direction with altitude. Increasing this parameter increases how rapidly the wind states adapt when changing altitude, but does make wind velocity estimation noiser.
This is a 1 byte bitmap controlling which GPS preflight checks are performed. Set to 0 to bypass all checks. Set to 255 perform all checks. Set to 3 to check just the number of satellites and HDoP. Set to 31 for the most rigorous checks that will still allow checks to pass when the copter is moving, eg launch from a boat.
1 byte bitmap of IMUs to use in EKF2. A separate instance of EKF2 will be started for each IMU selected. Set to 1 to use the first IMU only (default), set to 2 to use the second IMU only, set to 3 to use the first and second IMU. Additional IMU's can be used up to a maximum of 6 if memory and processing resources permit. There may be insufficient memory and processing resources to run multiple instances. If this occurs EKF2 will fail to start.
This scales the thresholds that are used to check GPS accuracy before it is used by the EKF. A value of 100 is the default. Values greater than 100 increase and values less than 100 reduce the maximum GPS error the EKF will accept. A value of 200 will double the allowable GPS error.
This sets the amount of position variation that the EKF allows for when operating without external measurements (eg GPS or optical flow). Increasing this parameter makes the EKF attitude estimate less sensitive to vehicle manoeuvres but more sensitive to IMU errors.
This is the RMS value of noise in yaw measurements from the magnetometer. Increasing it reduces the weighting on these measurements.
This sets the percentage number of standard deviations applied to the magnetometer yaw measurement innovation consistency check. Decreasing it makes it more likely that good measurements will be rejected. Increasing it makes it more likely that bad measurements will be accepted.
Sets the time constant of the output complementary filter/predictor in centi-seconds.
This state process noise controls the growth of earth magnetic field state error estimates. Increasing it makes earth magnetic field estimation faster and noisier.
This state process noise controls the growth of body magnetic field state error estimates. Increasing it makes magnetometer bias error estimation faster and noisier.
Range finder can be used as the primary height source when below this percentage of its maximum range (see RNGFND*_MAX). This will not work unless Baro or GPS height is selected as the primary height source vis EK2_ALT_SOURCE = 0 or 2 respectively. This feature should not be used for terrain following as it is designed for vertical takeoff and landing with climb above the range finder use height before commencing the mission, and with horizontal position changes below that height being limited to a flat region around the takeoff and landing point.
Specifies the maximum gradient of the terrain below the vehicle assumed when it is fusing range finder or optical flow to estimate terrain height.
This is the RMS value of noise in the range beacon measurement. Increasing it reduces the weighting on this measurement.
This sets the percentage number of standard deviations applied to the range beacon measurement innovation consistency check. Decreasing it makes it more likely that good measurements will be rejected. Increasing it makes it more likely that bad measurements will be accepted.
This is the number of msec that the range beacon measurements lag behind the inertial measurements. It is the time from the end of the optical flow averaging period and does not include the time delay due to the 100msec of averaging within the flow sensor.
The range finder will not be used as the primary height source when the horizontal ground speed is greater than this value.
1 byte bitmap of EKF cores that will disable magnetic field states and use simple magnetic heading fusion at all times. This parameter enables specified cores to be used as a backup for flight into an environment with high levels of external magnetic interference which may degrade the EKF attitude estimate when using 3-axis magnetometer fusion. NOTE : Use of a different magnetometer fusion algorithm on different cores makes unwanted EKF core switches due to magnetometer errors more likely.
When a height sensor other than GPS is used as the primary height source by the EKF, the position of the zero height datum is defined by that sensor and its frame of reference. If a GPS height measurement is also available, then the height of the WGS-84 height datum used by the EKF can be corrected so that the height returned by the getLLH() function is compensated for primary height sensor drift and change in datum over time. The first two bit positions control when the height datum will be corrected. Correction is performed using a Bayes filter and only operates when GPS quality permits. The third bit position controls where the corrections to the GPS reference datum are applied. Corrections can be applied to the local vertical position or to the reported EKF origin height (default).
Controls if the optical flow data is fused into the 24-state navigation estimator OR the 1-state terrain height estimator.
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Navigation |
| 2 | Terrain |
This limits the difference between the learned earth magnetic field and the earth field from the world magnetic model tables. A value of zero means to disable the use of the WMM tables.
Specifies the crossover frequency of the complementary filter used to calculate the output predictor height rate derivative.
A bitmask of which EKF2 instances run an independant EKF-GSF yaw estimator to provide a backup yaw estimate that doesn't rely on magnetometer data. This estimator uses IMU, GPS and, if available, airspeed data. EKF-GSF yaw estimator data for the primary EKF2 instance will be logged as GSF0 and GSF1 messages. Use of the yaw estimate generated by this algorithm is controlled by the EK2_GSF_USE_MASK and EK2_GSF_RST_MAX parameters. To run the EKF-GSF yaw estimator in ride-along and logging only, set EK2_GSF_USE_MASK to 0.
1 byte bitmap of which EKF2 instances will use the output from the EKF-GSF yaw estimator that has been turned on by the EK2_GSF_RUN_MASK parameter. If the inertial navigation calculation stops following the GPS, then the vehicle code can request EKF2 to attempt to resolve the issue, either by performing a yaw reset if enabled by this parameter by switching to another EKF2 instance.
Sets the maximum number of times the EKF2 will be allowed to reset its yaw to the estimate from the EKF-GSF yaw estimator. No resets will be allowed unless the use of the EKF-GSF yaw estimate is enabled via the EK2_GSF_USE_MASK parameter.
optional EKF2 behaviour. Disabling external navigation prevents use of external vision data in the EKF2 solution
This enables EKF3. Enabling EKF3 only makes the maths run, it does not mean it will be used for flight control. To use it for flight control set AHRS_EKF_TYPE=3. A reboot or restart will need to be performed after changing the value of EK3_ENABLE for it to take effect.
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
This sets a lower limit on the speed accuracy reported by the GPS receiver that is used to set horizontal velocity observation noise. If the model of receiver used does not provide a speed accurcy estimate, then the parameter value will be used. Increasing it reduces the weighting of the GPS horizontal velocity measurements.
This sets a lower limit on the speed accuracy reported by the GPS receiver that is used to set vertical velocity observation noise. If the model of receiver used does not provide a speed accurcy estimate, then the parameter value will be used. Increasing it reduces the weighting of the GPS vertical velocity measurements.
This sets the percentage number of standard deviations applied to the GPS velocity measurement innovation consistency check. Decreasing it makes it more likely that good measurements will be rejected. Increasing it makes it more likely that bad measurements will be accepted. If EK3_GLITCH_RAD set to 0 the velocity innovations will be clipped instead of rejected if they exceed the gate size and a smaller value of EK3_VEL_I_GATE not exceeding 300 is recommended to limit the effect of GPS transient errors.
This sets the GPS horizontal position observation noise. Increasing it reduces the weighting of GPS horizontal position measurements.
This sets the percentage number of standard deviations applied to the GPS position measurement innovation consistency check. Decreasing it makes it more likely that good measurements will be rejected. Increasing it makes it more likely that bad measurements will be accepted. If EK3_GLITCH_RAD has been set to 0 the horizontal position innovations will be clipped instead of rejected if they exceed the gate size so a smaller value of EK3_POS_I_GATE not exceeding 300 is recommended to limit the effect of GPS transient errors.
This controls the maximum radial uncertainty in position between the value predicted by the filter and the value measured by the GPS before the filter position and velocity states are reset to the GPS. Making this value larger allows the filter to ignore larger GPS glitches but also means that non-GPS errors such as IMU and compass can create a larger error in position before the filter is forced back to the GPS position. If EK3_GLITCH_RAD set to 0 the GPS innovations will be clipped instead of rejected if they exceed the gate size set by EK3_VEL_I_GATE and EK3_POS_I_GATE which can be useful if poor quality sensor data is causing GPS rejection and loss of navigation but does make the EKF more susceptible to GPS glitches. If setting EK3_GLITCH_RAD to 0 it is recommended to reduce EK3_VEL_I_GATE and EK3_POS_I_GATE to 300.
This is the RMS value of noise in the altitude measurement. Increasing it reduces the weighting of the baro measurement and will make the filter respond more slowly to baro measurement errors, but will make it more sensitive to GPS and accelerometer errors. A larger value for EK3_ALT_M_NSE may be required when operating with EK3_SRCx_POSZ = 0. This parameter also sets the noise for the 'synthetic' zero height measurement that is used when EK3_SRCx_POSZ = 0.
This sets the percentage number of standard deviations applied to the height measurement innovation consistency check. Decreasing it makes it more likely that good measurements will be rejected. Increasing it makes it more likely that bad measurements will be accepted. If EK3_GLITCH_RAD set to 0 the vertical position innovations will be clipped instead of rejected if they exceed the gate size and a smaller value of EK3_HGT_I_GATE not exceeding 300 is recommended to limit the effect of height sensor transient errors.
This is the number of msec that the Height measurements lag behind the inertial measurements.
This is the RMS value of noise in magnetometer measurements. Increasing it reduces the weighting on these measurements.
This determines when the filter will use the 3-axis magnetometer fusion model that estimates both earth and body fixed magnetic field states and when it will use a simpler magnetic heading fusion model that does not use magnetic field states. The 3-axis magnetometer fusion is only suitable for use when the external magnetic field environment is stable. EK3_MAG_CAL = 0 uses heading fusion on ground, 3-axis fusion in-flight, and is the default setting for Plane users. EK3_MAG_CAL = 1 uses 3-axis fusion only when manoeuvring. EK3_MAG_CAL = 2 uses heading fusion at all times, is recommended if the external magnetic field is varying and is the default for rovers. EK3_MAG_CAL = 3 uses heading fusion on the ground and 3-axis fusion after the first in-air field and yaw reset has completed, and is the default for copters. EK3_MAG_CAL = 4 uses 3-axis fusion at all times. EK3_MAG_CAL = 5 uses an external yaw sensor with simple heading fusion. NOTE : Use of simple heading magnetometer fusion makes vehicle compass calibration and alignment errors harder for the EKF to detect which reduces the sensitivity of the Copter EKF failsafe algorithm. NOTE: The fusion mode can be forced to 2 for specific EKF cores using the EK3_MAG_MASK parameter. EK3_MAG_CAL = 6 uses an external yaw sensor with fallback to compass when the external sensor is not available if we are flying. NOTE: The fusion mode can be forced to 2 for specific EKF cores using the EK3_MAG_MASK parameter. NOTE: limited operation without a magnetometer or any other yaw sensor is possible by setting all COMPASS_USE, COMPASS_USE2, COMPASS_USE3, etc parameters to 0 and setting COMPASS_ENABLE to 0. If this is done, the EK3_GSF_RUN and EK3_GSF_USE masks must be set to the same as EK3_IMU_MASK. A yaw angle derived from IMU and GPS velocity data using a Gaussian Sum Filter (GSF) will then be used to align the yaw when flight commences and there is sufficient movement.
| Value | Meaning |
|---|---|
| 0 | When flying |
| 1 | When manoeuvring |
| 2 | Never |
| 3 | After first climb yaw reset |
| 4 | Always |
| 5 | Use external yaw sensor (Deprecated in 4.1+ see EK3_SRCn_YAW) |
| 6 | External yaw sensor with compass fallback (Deprecated in 4.1+ see EK3_SRCn_YAW) |
This sets the percentage number of standard deviations applied to the magnetometer measurement innovation consistency check. Decreasing it makes it more likely that good measurements will be rejected. Increasing it makes it more likely that bad measurements will be accepted.
This is the RMS value of noise in equivalent airspeed measurements used by planes. Increasing it reduces the weighting of airspeed measurements and will make wind speed estimates less noisy and slower to converge. Increasing also increases navigation errors when dead-reckoning without GPS measurements.
This sets the percentage number of standard deviations applied to the airspeed measurement innovation consistency check. Decreasing it makes it more likely that good measurements will be rejected. Increasing it makes it more likely that bad measurements will be accepted.
This is the RMS value of noise in the range finder measurement. Increasing it reduces the weighting on this measurement.
This sets the percentage number of standard deviations applied to the range finder innovation consistency check. Decreasing it makes it more likely that good measurements will be rejected. Increasing it makes it more likely that bad measurements will be accepted.
The maximum optical flow rate in rad/sec that will be accepted by the filter. Flow rates above this value will not be fused.
This is the RMS value of noise and errors in optical flow measurements. Increasing it reduces the weighting on these measurements.
This sets the percentage number of standard deviations applied to the optical flow innovation consistency check. Decreasing it makes it more likely that good measurements will be rejected. Increasing it makes it more likely that bad measurements will be accepted.
This is the number of msec that the optical flow measurements lag behind the inertial measurements. It is the time from the end of the optical flow averaging period and does not include the time delay due to the 100msec of averaging within the flow sensor.
This control disturbance noise controls the growth of estimated error due to gyro measurement errors excluding bias. Increasing it makes the flter trust the gyro measurements less and other measurements more.
This control disturbance noise controls the growth of estimated error due to accelerometer measurement errors excluding bias. Increasing it makes the flter trust the accelerometer measurements less and other measurements more.
This state process noise controls growth of the gyro delta angle bias state error estimate. Increasing it makes rate gyro bias estimation faster and noisier.
This noise controls the growth of the vertical accelerometer delta velocity bias state error estimate. Increasing it makes accelerometer bias estimation faster and noisier.
This state process noise controls the growth of wind state error estimates. Increasing it makes wind estimation faster and noisier.
This controls how much the process noise on the wind states is increased when gaining or losing altitude to take into account changes in wind speed and direction with altitude. Increasing this parameter increases how rapidly the wind states adapt when changing altitude, but does make wind velocity estimation noiser.
This is a 1 byte bitmap controlling which GPS preflight checks are performed. Set to 0 to bypass all checks. Set to 255 perform all checks. Set to 3 to check just the number of satellites and HDoP. Set to 31 for the most rigorous checks that will still allow checks to pass when the copter is moving, eg launch from a boat.
1 byte bitmap of IMUs to use in EKF3. A separate instance of EKF3 will be started for each IMU selected. Set to 1 to use the first IMU only (default), set to 2 to use the second IMU only, set to 3 to use the first and second IMU. Additional IMU's can be used up to a maximum of 6 if memory and processing resources permit. There may be insufficient memory and processing resources to run multiple instances. If this occurs EKF3 will fail to start.
This scales the thresholds that are used to check GPS accuracy before it is used by the EKF. A value of 100 is the default. Values greater than 100 increase and values less than 100 reduce the maximum GPS error the EKF will accept. A value of 200 will double the allowable GPS error.
This sets the amount of position variation that the EKF allows for when operating without external measurements (eg GPS or optical flow). Increasing this parameter makes the EKF attitude estimate less sensitive to vehicle manoeuvres but more sensitive to IMU errors.
1 byte bitmap controlling use of sideslip angle fusion for estimation of non wind states during operation of 'fly forward' vehicle types such as fixed wing planes. By assuming that the angle of sideslip is small, the wind velocity state estimates are corrected whenever the EKF is not dead reckoning (e.g. has an independent velocity or position sensor such as GPS). This behaviour is on by default and cannot be disabled. When the EKF is dead reckoning, the wind states are used as a reference, enabling use of the small angle of sideslip assumption to correct non wind velocity states (eg attitude, velocity, position, etc) and improve navigation accuracy. This behaviour is on by default and cannot be disabled. The behaviour controlled by this parameter is the use of the small angle of sideslip assumption to correct non wind velocity states when the EKF is NOT dead reckoning. This is primarily of benefit to reduce the buildup of yaw angle errors during straight and level flight without a yaw sensor (e.g. magnetometer or dual antenna GPS yaw) provided aerobatic flight maneuvers with large sideslip angles are not performed. The 'always' option might be used where the yaw sensor is intentionally not fitted or disabled. The 'WhenNoYawSensor' option might be used if a yaw sensor is fitted, but protection against in-flight failure and continual rejection by the EKF is desired. For vehicles operated within visual range of the operator performing frequent turning maneuvers, setting this parameter is unnecessary.
This is the RMS value of noise in yaw measurements from the magnetometer. Increasing it reduces the weighting on these measurements.
This sets the percentage number of standard deviations applied to the magnetometer yaw measurement innovation consistency check. Decreasing it makes it more likely that good measurements will be rejected. Increasing it makes it more likely that bad measurements will be accepted.
Sets the time constant of the output complementary filter/predictor in centi-seconds.
This state process noise controls the growth of earth magnetic field state error estimates. Increasing it makes earth magnetic field estimation faster and noisier.
This state process noise controls the growth of body magnetic field state error estimates. Increasing it makes magnetometer bias error estimation faster and noisier.
Range finder can be used as the primary height source when below this percentage of its maximum range (see RNGFNDx_MAX) and the primary height source is Baro or GPS (see EK3_SRCx_POSZ). This feature should not be used for terrain following as it is designed for vertical takeoff and landing with climb above the range finder use height before commencing the mission, and with horizontal position changes below that height being limited to a flat region around the takeoff and landing point.
Specifies the maximum gradient of the terrain below the vehicle when it is using range finder as a height reference
This is the RMS value of noise in the range beacon measurement. Increasing it reduces the weighting on this measurement.
This sets the percentage number of standard deviations applied to the range beacon measurement innovation consistency check. Decreasing it makes it more likely that good measurements will be rejected. Increasing it makes it more likely that bad measurements will be accepted.
This is the number of msec that the range beacon measurements lag behind the inertial measurements.
The range finder will not be used as the primary height source when the horizontal ground speed is greater than this value.
The accelerometer bias state will be limited to +- this value
1 byte bitmap of EKF cores that will disable magnetic field states and use simple magnetic heading fusion at all times. This parameter enables specified cores to be used as a backup for flight into an environment with high levels of external magnetic interference which may degrade the EKF attitude estimate when using 3-axis magnetometer fusion. NOTE : Use of a different magnetometer fusion algorithm on different cores makes unwanted EKF core switches due to magnetometer errors more likely.
When a height sensor other than GPS is used as the primary height source by the EKF, the position of the zero height datum is defined by that sensor and its frame of reference. If a GPS height measurement is also available, then the height of the WGS-84 height datum used by the EKF can be corrected so that the height returned by the getLLH() function is compensated for primary height sensor drift and change in datum over time. The first two bit positions control when the height datum will be corrected. Correction is performed using a Bayes filter and only operates when GPS quality permits. The third bit position controls where the corrections to the GPS reference datum are applied. Corrections can be applied to the local vertical position or to the reported EKF origin height (default).
This is the 1-STD odometry velocity observation error that will be assumed when maximum quality is reported by the sensor. When quality is between max and min, the error will be calculated using linear interpolation between VIS_VERR_MIN and VIS_VERR_MAX.
This is the 1-STD odometry velocity observation error that will be assumed when minimum quality is reported by the sensor. When quality is between max and min, the error will be calculated using linear interpolation between VIS_VERR_MIN and VIS_VERR_MAX.
This is the 1-STD odometry velocity observation error that will be assumed when wheel encoder data is being fused.
Controls if the optical flow data is fused into the 24-state navigation estimator OR the 1-state terrain height estimator.
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Navigation |
| 2 | Terrain |
Specifies the crossover frequency of the complementary filter used to calculate the output predictor height rate derivative.
This limits the difference between the learned earth magnetic field and the earth field from the world magnetic model tables. A value of zero means to disable the use of the WMM tables.
1 byte bitmap of which EKF3 instances run an independent EKF-GSF yaw estimator to provide a backup yaw estimate that doesn't rely on magnetometer data. This estimator uses IMU, GPS and, if available, airspeed data. EKF-GSF yaw estimator data for the primary EKF3 instance will be logged as GSF0 and GSF1 messages. Use of the yaw estimate generated by this algorithm is controlled by the EK3_GSF_USE_MASK and EK3_GSF_RST_MAX parameters. To run the EKF-GSF yaw estimator in ride-along and logging only, set EK3_GSF_USE to 0.
A bitmask of which EKF3 instances will use the output from the EKF-GSF yaw estimator that has been turned on by the EK3_GSF_RUN_MASK parameter. If the inertial navigation calculation stops following the GPS, then the vehicle code can request EKF3 to attempt to resolve the issue, either by performing a yaw reset if enabled by this parameter by switching to another EKF3 instance.
Sets the maximum number of times the EKF3 will be allowed to reset its yaw to the estimate from the EKF-GSF yaw estimator. No resets will be allowed unless the use of the EKF-GSF yaw estimate is enabled via the EK3_GSF_USE_MASK parameter.
lanes have to be consistently better than the primary by at least this threshold to reduce their overall relativeCoreError, lowering this makes lane switching more sensitive to smaller error differences
These options control the affinity between sensor instances and EKF cores
Ratio of mass to drag coefficient measured along the X body axis. This parameter enables estimation of wind drift for vehicles with bluff bodies and without propulsion forces in the X and Y direction (eg multicopters). The drag produced by this effect scales with speed squared. Set to a positive value > 1.0 to enable. A starting value is the mass in Kg divided by the frontal area. The predicted drag from the rotors is specified separately by the EK3_DRAG_MCOEF parameter.
Ratio of mass to drag coefficient measured along the Y body axis. This parameter enables estimation of wind drift for vehicles with bluff bodies and without propulsion forces in the X and Y direction (eg multicopters). The drag produced by this effect scales with speed squared. Set to a positive value > 1.0 to enable. A starting value is the mass in Kg divided by the side area. The predicted drag from the rotors is specified separately by the EK3_DRAG_MCOEF parameter.
This sets the amount of noise used when fusing X and Y acceleration as an observation that enables estimation of wind velocity for multi-rotor vehicles. This feature is enabled by the EK3_DRAG_BCOEF_X and EK3_DRAG_BCOEF_Y parameters
This parameter is used to predict the drag produced by the rotors when flying a multi-copter, enabling estimation of wind drift. The drag produced by this effect scales with speed not speed squared and is produced because some of the air velocity normal to the rotors axis of rotation is lost when passing through the rotor disc which changes the momentum of the airflow causing drag. For unducted rotors the effect is roughly proportional to the area of the propeller blades when viewed side on and changes with different propellers. It is higher for ducted rotors. For example if flying at 15 m/s at sea level conditions produces a rotor induced drag acceleration of 1.5 m/s/s, then EK3_DRAG_MCOEF would be set to 0.1 = (1.5/15.0). Set EK3_MCOEF to a positive value to enable wind estimation using this drag effect. To account for the drag produced by the body which scales with speed squared, see documentation for the EK3_DRAG_BCOEF_X and EK3_DRAG_BCOEF_Y parameters.
This parameter is adjust the sensitivity of the on ground not moving test which is used to assist with learning the yaw gyro bias and stopping yaw drift before flight when operating without a yaw sensor. Bigger values allow the detection of a not moving condition with noiser IMU data. Check the XKFM data logged when the vehicle is on ground not moving and adjust the value of OGNM_TEST_SF to be slightly higher than the maximum value of the XKFM.ADR, XKFM.ALR, XKFM.GDR and XKFM.GLR test levels.
This parameter sets the size of the dead zone that is applied to negative baro height spikes that can occur when taking off or landing when a vehicle with lift rotors is operating in ground effect ground effect. Set to about 0.5m less than the amount of negative offset in baro height that occurs just prior to takeoff when lift motors are spooling up. Set to 0 if no ground effect is present.
The core number (index in IMU mask) that will be used as the primary EKF core on startup. While disarmed the EKF will force the use of this core. A value of 0 corresponds to the first IMU in EK3_IMU_MASK.
Determines how verbose the EKF3 streaming logging is. A value of 0 provides full logging(default), a value of 1 only XKF4 scaled innovations are logged, a value of 2 both XKF4 and GSF are logged, and a value of 3 disables all streaming logging of EKF3.
Vertical accuracy threshold for GPS as the altitude source. The GPS will not be used as an altitude source if the reported vertical accuracy of the GPS is larger than this threshold, falling back to baro instead. Set to zero to deactivate the threshold check.
EKF optional behaviour. Bit 0 (JammingExpected): Setting JammingExpected will change the EKF behaviour such that if dead reckoning navigation is possible it will require the preflight alignment GPS quality checks controlled by EK3_GPS_CHECK and EK3_CHECK_SCALE to pass before resuming GPS use if GPS lock is lost for more than 2 seconds to prevent bad position estimate. Bit 1 (Manual lane switching): DANGEROUS – If enabled, this disables automatic lane switching. If the active lane becomes unhealthy, no automatic switching will occur. Users must manually set EK3_PRIMARY to change lanes. No health checks will be performed on the selected lane. Use with extreme caution. Bit 2 (Optflow may use terrain alt): Terrain SRTM data will be used if the vehicle climbs above the rangefinder's range allowing optical flow to be used at higher altitudes.
Position Horizontal Source (Primary)
| Value | Meaning |
|---|---|
| 0 | None |
| 3 | GPS |
| 4 | Beacon |
| 6 | ExternalNav |
Velocity Horizontal Source
| Value | Meaning |
|---|---|
| 0 | None |
| 3 | GPS |
| 4 | Beacon |
| 5 | OpticalFlow |
| 6 | ExternalNav |
| 7 | WheelEncoder |
Position Vertical Source
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Baro |
| 2 | RangeFinder |
| 3 | GPS |
| 4 | Beacon |
| 6 | ExternalNav |
Velocity Vertical Source
| Value | Meaning |
|---|---|
| 0 | None |
| 3 | GPS |
| 4 | Beacon |
| 6 | ExternalNav |
Yaw Source
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Compass |
| 2 | GPS |
| 3 | GPS with Compass Fallback |
| 6 | ExternalNav |
| 8 | GSF |
Position Horizontal Source (Secondary)
| Value | Meaning |
|---|---|
| 0 | None |
| 3 | GPS |
| 4 | Beacon |
| 6 | ExternalNav |
Velocity Horizontal Source (Secondary)
| Value | Meaning |
|---|---|
| 0 | None |
| 3 | GPS |
| 4 | Beacon |
| 5 | OpticalFlow |
| 6 | ExternalNav |
| 7 | WheelEncoder |
Position Vertical Source (Secondary)
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Baro |
| 2 | RangeFinder |
| 3 | GPS |
| 4 | Beacon |
| 6 | ExternalNav |
Velocity Vertical Source (Secondary)
| Value | Meaning |
|---|---|
| 0 | None |
| 3 | GPS |
| 4 | Beacon |
| 6 | ExternalNav |
Yaw Source (Secondary)
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Compass |
| 2 | GPS |
| 3 | GPS with Compass Fallback |
| 6 | ExternalNav |
| 8 | GSF |
Position Horizontal Source (Tertiary)
| Value | Meaning |
|---|---|
| 0 | None |
| 3 | GPS |
| 4 | Beacon |
| 6 | ExternalNav |
Velocity Horizontal Source (Tertiary)
| Value | Meaning |
|---|---|
| 0 | None |
| 3 | GPS |
| 4 | Beacon |
| 5 | OpticalFlow |
| 6 | ExternalNav |
| 7 | WheelEncoder |
Position Vertical Source (Tertiary)
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Baro |
| 2 | RangeFinder |
| 3 | GPS |
| 4 | Beacon |
| 6 | ExternalNav |
Velocity Vertical Source (Tertiary)
| Value | Meaning |
|---|---|
| 0 | None |
| 3 | GPS |
| 4 | Beacon |
| 6 | ExternalNav |
Yaw Source (Tertiary)
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Compass |
| 2 | GPS |
| 3 | GPS with Compass Fallback |
| 6 | ExternalNav |
| 8 | GSF |
EKF Source Options. Bit 0: Fuse all velocity sources present in EK3_SRCx_VEL_. Bit 1: Align external navigation position when using optical flow. Bit 3: Use SRC per core. By default, EKF source selection is controlled via the EK3_SRC parameters, allowing only one source to be active at a time across all cores (switchable via MAVLink, Lua, or RC). Enabling this bit maps EKF core 1 to SRC1, core 2 to SRC2, etc., allowing each core to run independently with a dedicated source.
Offset to apply to ESC numbers when reporting as ESC_TELEMETRY packets over MAVLink. This allows high numbered motors to be displayed as low numbered ESCs for convenience on GCS displays. A value of 4 would send ESC on output 5 as ESC number 1 in ESC_TELEMETRY packets
Allows you to enable (1) or disable (0) the fence functionality. Fences can still be enabled and disabled via mavlink or an RC option, but these changes are not persisted.
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
What action should be taken when fence is breached
| Value | Meaning |
|---|---|
| 0 | Report Only |
| 1 | RTL or Land |
Circle fence radius which when breached will cause an RTL
Distance that autopilot's should maintain from the fence to avoid a breach
Number of polygon points saved in eeprom (do not update manually)
When bit 0 is set disable mode change following fence action until fence breach is cleared. When bit 1 is set the allowable flight areas is the union of all polygon and circle fence areas instead of the intersection, which means a fence breach occurs only if you are outside all of the fence areas.
When bit 2 of FENCE_OPTIONS is set this parameter controls the frequency of margin breach notifications. If set to 0 only new margin breaches are notified.
Enable Gyro FFT analyser
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
Lower bound of FFT frequency detection in Hz. On larger vehicles the minimum motor frequency is likely to be significantly lower than for smaller vehicles.
Upper bound of FFT frequency detection in Hz. On smaller vehicles the maximum motor frequency is likely to be significantly higher than for larger vehicles.
Sampling mode (and therefore rate). 0: Gyro rate sampling, 1: Fast loop rate sampling, 2: Fast loop rate / 2 sampling, 3: Fast loop rate / 3 sampling. Takes effect on reboot.
Size of window to be used in FFT calculations. Takes effect on reboot. Must be a power of 2 and between 32 and 512. Larger windows give greater frequency resolution but poorer time resolution, consume more CPU time and may not be appropriate for all vehicles. Time and frequency resolution are given by the sample-rate / window-size. Windows of 256 are only really recommended for F7 class boards, windows of 512 or more H7 class.
Percentage of window to be overlapped before another frame is process. Takes effect on reboot. A good default is 50% overlap. Higher overlap results in more processed frames but not necessarily more temporal resolution. Lower overlap results in lost information at the frame edges.
The learned hover noise frequency
FFT learned thrust reference for the hover frequency and FFT minimum frequency.
FFT SNR reference threshold in dB at which a signal is determined to be present.
FFT attenuation level in dB for bandwidth calculation and peak detection. The bandwidth is calculated by comparing peak power output with the attenuated version. The default of 15 has shown to be a good compromise in both simulations and real flight.
FFT learned bandwidth at hover for the attenuation frequencies.
FFT harmonic fit frequency threshold percentage at which a signal of the appropriate frequency is determined to be the harmonic of another. Signals that have a harmonic relationship that varies at most by this percentage are considered harmonics of each other for the purpose of selecting the harmonic notch frequency. If a match is found then the lower frequency harmonic is always used as the basis for the dynamic harmonic notch. A value of zero completely disables harmonic matching.
The FFT harmonic peak target that should be returned by FTN1.PkAvg. The resulting value will be used by the harmonic notch if configured to track the FFT frequency. By default the appropriate peak is auto-detected based on the harmonic fit between peaks and the energy-weighted average frequency on roll on pitch is used. Setting this to 1 will always target the highest energy peak. Setting this to 2 will target the highest energy peak that is lower in frequency than the highest energy peak. Setting this to 3 will target the highest energy peak that is higher in frequency than the highest energy peak. Setting this to 4 will target the highest energy peak on the roll axis only and only the roll frequency will be used (some vehicles have a much more pronounced peak on roll). Setting this to 5 will target the highest energy peak on the pitch axis only and only the pitch frequency will be used (some vehicles have a much more pronounced peak on roll).
| Value | Meaning |
|---|---|
| 0 | Auto |
| 1 | Center Frequency |
| 2 | Lower-Shoulder Frequency |
| 3 | Upper-Shoulder Frequency |
| 4 | Roll-Axis |
| 5 | Pitch-Axis |
Number of output frequency frames to retain and average in order to calculate final frequencies. Averaging output frames can drastically reduce noise and jitter at the cost of latency as long as the input is stable. The default is to perform no averaging. For rapidly changing frequencies (e.g. smaller aircraft) fewer frames should be averaged.
FFT configuration options. Values: 1:Apply the FFT *after* the filter bank,2:Check noise at the motor frequencies using ESC data as a reference
Filter Type
| Value | Meaning |
|---|---|
| 0 | Disable |
| 1 | Notch Filter |
Notch Filter center frequency in Hz.
Notch Filter quality factor given by the notch centre frequency divided by its bandwidth.
Notch Filter attenuation in dB.
Filter Type
| Value | Meaning |
|---|---|
| 0 | Disable |
| 1 | Notch Filter |
Notch Filter center frequency in Hz.
Notch Filter quality factor given by the notch centre frequency divided by its bandwidth.
Notch Filter attenuation in dB.
Filter Type
| Value | Meaning |
|---|---|
| 0 | Disable |
| 1 | Notch Filter |
Notch Filter center frequency in Hz.
Notch Filter quality factor given by the notch centre frequency divided by its bandwidth.
Notch Filter attenuation in dB.
Filter Type
| Value | Meaning |
|---|---|
| 0 | Disable |
| 1 | Notch Filter |
Notch Filter center frequency in Hz.
Notch Filter quality factor given by the notch centre frequency divided by its bandwidth.
Notch Filter attenuation in dB.
Filter Type
| Value | Meaning |
|---|---|
| 0 | Disable |
| 1 | Notch Filter |
Notch Filter center frequency in Hz.
Notch Filter quality factor given by the notch centre frequency divided by its bandwidth.
Notch Filter attenuation in dB.
Filter Type
| Value | Meaning |
|---|---|
| 0 | Disable |
| 1 | Notch Filter |
Notch Filter center frequency in Hz.
Notch Filter quality factor given by the notch centre frequency divided by its bandwidth.
Notch Filter attenuation in dB.
Filter Type
| Value | Meaning |
|---|---|
| 0 | Disable |
| 1 | Notch Filter |
Notch Filter center frequency in Hz.
Notch Filter quality factor given by the notch centre frequency divided by its bandwidth.
Notch Filter attenuation in dB.
Filter Type
| Value | Meaning |
|---|---|
| 0 | Disable |
| 1 | Notch Filter |
Notch Filter center frequency in Hz.
Notch Filter quality factor given by the notch centre frequency divided by its bandwidth.
Notch Filter attenuation in dB.
This is the oscillation frequency of the fins
Enables double speed on high offset.
Change the uplink sensor id (SPort only)
| Value | Meaning |
|---|---|
| -1 | Disable |
| 7 | 7 |
| 8 | 8 |
| 9 | 9 |
| 10 | 10 |
| 11 | 11 |
| 12 | 12 |
| 13 | 13 |
| 14 | 14 |
| 15 | 15 |
| 16 | 16 |
| 17 | 17 |
| 18 | 18 |
| 19 | 19 |
| 20 | 20 |
| 21 | 21 |
| 22 | 22 |
| 23 | 23 |
| 24 | 24 |
| 25 | 25 |
| 26 | 26 |
Change the first extra downlink sensor id (SPort only)
| Value | Meaning |
|---|---|
| -1 | Disable |
| 7 | 7 |
| 8 | 8 |
| 9 | 9 |
| 10 | 10 |
| 11 | 11 |
| 12 | 12 |
| 13 | 13 |
| 14 | 14 |
| 15 | 15 |
| 16 | 16 |
| 17 | 17 |
| 18 | 18 |
| 19 | 19 |
| 20 | 20 |
| 21 | 21 |
| 22 | 22 |
| 23 | 23 |
| 24 | 24 |
| 25 | 25 |
| 26 | 26 |
Change the second extra downlink sensor id (SPort only)
| Value | Meaning |
|---|---|
| -1 | Disable |
| 7 | 7 |
| 8 | 8 |
| 9 | 9 |
| 10 | 10 |
| 11 | 11 |
| 12 | 12 |
| 13 | 13 |
| 14 | 14 |
| 15 | 15 |
| 16 | 16 |
| 17 | 17 |
| 18 | 18 |
| 19 | 19 |
| 20 | 20 |
| 21 | 21 |
| 22 | 22 |
| 23 | 23 |
| 24 | 24 |
| 25 | 25 |
| 26 | 26 |
Change the default downlink sensor id (SPort only)
| Value | Meaning |
|---|---|
| -1 | Disable |
| 7 | 7 |
| 8 | 8 |
| 9 | 9 |
| 10 | 10 |
| 11 | 11 |
| 12 | 12 |
| 13 | 13 |
| 14 | 14 |
| 15 | 15 |
| 16 | 16 |
| 17 | 17 |
| 18 | 18 |
| 19 | 19 |
| 20 | 20 |
| 21 | 21 |
| 22 | 22 |
| 23 | 23 |
| 24 | 24 |
| 25 | 25 |
| 26 | 26 |
| 27 | 27 |
A bitmask to set some FRSky Telemetry specific options
Generator type
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | IE 650w 800w Fuel Cell |
| 2 | IE 2.4kW Fuel Cell |
| 3 | Richenpower |
| 4 | Loweheiser |
Bitmask of options for generators
Navigation filter engine setting
| Value | Meaning |
|---|---|
| 0 | Portable |
| 2 | Stationary |
| 3 | Pedestrian |
| 4 | Automotive |
| 5 | Sea |
| 6 | Airborne1G |
| 7 | Airborne2G |
| 8 | Airborne4G |
Automatic switchover to GPS reporting best lock, 1:UseBest selects the GPS with highest status, if both are equal the GPS with highest satellite count is used 4:Use primary if 3D fix or better, will revert to 'UseBest' behaviour if 3D fix is lost on primary
| Value | Meaning |
|---|---|
| 0 | Use primary |
| 1 | UseBest |
| 2 | Blend |
| 4 | Use primary if 3D fix or better |
This sets the SBAS (satellite based augmentation system) mode if available on this GPS. If set to 2 then the SBAS mode is not changed in the GPS. Otherwise the GPS will be reconfigured to enable/disable SBAS. Disabling SBAS may be worthwhile in some parts of the world where an SBAS signal is available but the baseline is too long to be useful.
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
| 2 | NoChange |
This sets the minimum elevation of satellites above the horizon for them to be used for navigation. Setting this to -100 leaves the minimum elevation set to the GPS modules default.
The GGS can send raw serial packets to inject data to multiple GPSes.
| Value | Meaning |
|---|---|
| 0 | send to first GPS |
| 1 | send to 2nd GPS |
| 127 | send to all |
Masked with the SBP msg_type field to determine whether SBR1/SBR2 data is logged
| Value | Meaning |
|---|---|
| 0 | None (0x0000) |
| -1 | All (0xFFFF) |
| -256 | External only (0xFF00) |
Handles logging raw data; on uBlox chips that support raw data this will log RXM messages into logger; on Septentrio this will log on the equipment's SD card and when set to 2, the autopilot will try to stop logging after disarming and restart after arming
| Value | Meaning |
|---|---|
| 0 | Ignore |
| 1 | Always log |
| 2 | Stop logging when disarmed (SBF only) |
| 5 | Only log every five samples (uBlox only) |
Determines whether the configuration for this GPS should be written to non-volatile memory on the GPS. Currently working for UBlox 6 series and above.
| Value | Meaning |
|---|---|
| 0 | Do not save config |
| 1 | Save config |
| 2 | Save only when needed |
Controls if the autopilot should automatically configure the GPS based on the parameters and default settings
| Value | Meaning |
|---|---|
| 0 | Disables automatic configuration |
| 1 | Enable automatic configuration for Serial GPSes only |
| 2 | Enable automatic configuration for DroneCAN as well |
Determines which of the accuracy measures Horizontal position, Vertical Position and Speed are used to calculate the weighting on each GPS receiver when soft switching has been selected by setting GPS_AUTO_SWITCH to 2(Blend)
Additional backend specific options
This GPS will be used when GPS_AUTO_SWITCH is 0 and used preferentially with GPS_AUTO_SWITCH = 4.
| Value | Meaning |
|---|---|
| 0 | FirstGPS |
| 1 | SecondGPS |
GPS type of 1st GPS.Renamed in 4.6 and later to GPS1_TYPE
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | AUTO |
| 2 | uBlox |
| 5 | NMEA |
| 6 | SiRF |
| 7 | HIL |
| 8 | SwiftNav |
| 9 | DroneCAN |
| 10 | SBF |
| 11 | GSOF |
| 13 | ERB |
| 14 | MAV |
| 15 | NOVA |
| 16 | HemisphereNMEA |
| 17 | uBlox-MovingBaseline-Base |
| 18 | uBlox-MovingBaseline-Rover |
| 19 | MSP |
| 20 | AllyStar |
| 21 | ExternalAHRS |
| 22 | DroneCAN-MovingBaseline-Base |
| 23 | DroneCAN-MovingBaseline-Rover |
| 24 | UnicoreNMEA |
| 25 | UnicoreMovingBaselineNMEA |
| 26 | SBF-DualAntenna |
GPS type of 2nd GPS
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | AUTO |
| 2 | uBlox |
| 5 | NMEA |
| 6 | SiRF |
| 7 | HIL |
| 8 | SwiftNav |
| 9 | DroneCAN |
| 10 | SBF |
| 11 | GSOF |
| 13 | ERB |
| 14 | MAV |
| 15 | NOVA |
| 16 | HemisphereNMEA |
| 17 | uBlox-MovingBaseline-Base |
| 18 | uBlox-MovingBaseline-Rover |
| 19 | MSP |
| 20 | AllyStar |
| 21 | ExternalAHRS |
| 22 | DroneCAN-MovingBaseline-Base |
| 23 | DroneCAN-MovingBaseline-Rover |
| 24 | UnicoreNMEA |
| 25 | UnicoreMovingBaselineNMEA |
| 26 | SBF-DualAntenna |
Bitmask for what GNSS system to use on the first GPS (all unchecked or zero to leave GPS as configured).Renamed in 4.6 and later to GPS1_GNSS_MODE.
Bitmask for what GNSS system to use on the second GPS (all unchecked or zero to leave GPS as configured). Renamed in 4.6 and later to GPS2_GNSS_MODE
Controls how often the GPS should provide a position update. Lowering below 5Hz(default) is not allowed. Raising the rate above 5Hz usually provides little benefit and for some GPS (eg Ublox M9N) can severely impact performance.Renamed in 4.6 and later to GPS1_RATE_MS
| Value | Meaning |
|---|---|
| 100 | 10Hz |
| 125 | 8Hz |
| 200 | 5Hz |
Controls how often the GPS should provide a position update. Lowering below 5Hz(default) is not allowed. Raising the rate above 5Hz usually provides little benefit and for some GPS (eg Ublox M9N) can severely impact performance.Renamed in 4.6 and later to GPS2_RATE_MS
| Value | Meaning |
|---|---|
| 100 | 10Hz |
| 125 | 8Hz |
| 200 | 5Hz |
X position of the first GPS antenna in body frame. Positive X is forward of the origin. Use antenna phase centroid location if provided by the manufacturer.Renamed in 4.6 and later to GPS1_POS_X.
Y position of the first GPS antenna in body frame. Positive Y is to the right of the origin. Use antenna phase centroid location if provided by the manufacturer.Renamed in 4.6 and later to GPS1_POS_Y.
Z position of the first GPS antenna in body frame. Positive Z is down from the origin. Use antenna phase centroid location if provided by the manufacturer.Renamed in 4.6 and later to GPS1_POS_Z.
X position of the second GPS antenna in body frame. Positive X is forward of the origin. Use antenna phase centroid location if provided by the manufacturer.Renamed in 4.6 and later to GPS2_POS_X.
Y position of the second GPS antenna in body frame. Positive Y is to the right of the origin. Use antenna phase centroid location if provided by the manufacturer.Renamed in 4.6 and later to GPS2_POS_Y.
Z position of the second GPS antenna in body frame. Positive Z is down from the origin. Use antenna phase centroid location if provided by the manufacturer.Renamed in 4.6 and later to GPS2_POS_Z.
Controls the amount of GPS measurement delay that the autopilot compensates for. Set to zero to use the default delay for the detected GPS type.Renamed in 4.6 and later to GPS1_DELAY_MS.
Controls the amount of GPS measurement delay that the autopilot compensates for. Set to zero to use the default delay for the detected GPS type.Renamed in 4.6 and later to GPS2_DELAY_MS.
The physical COM port on the connected device, currently only applies to SBF and GSOF GPS,Renamed in 4.6 and later to GPS1_COM_PORT.
| Value | Meaning |
|---|---|
| 0 | COM1(RS232) on GSOF |
| 1 | COM2(TTL) on GSOF |
The physical COM port on the connected device, currently only applies to SBF and GSOF GPS.Renamed in 4.6 and later to GPS1_COM_PORT.
GPS Node id for first-discovered GPS.Renamed in 4.6 and later to GPS1_CAN_NODEID.
GPS Node id for second-discovered GPS.Renamed in 4.6 and later to GPS2_CAN_NODEID.
GPS type
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | AUTO |
| 2 | uBlox |
| 5 | NMEA |
| 6 | SiRF |
| 7 | HIL |
| 8 | SwiftNav |
| 9 | DroneCAN |
| 10 | Septentrio(SBF) |
| 11 | Trimble(GSOF) |
| 13 | ERB |
| 14 | MAVLink |
| 15 | NOVA |
| 16 | HemisphereNMEA |
| 17 | uBlox-MovingBaseline-Base |
| 18 | uBlox-MovingBaseline-Rover |
| 19 | MSP |
| 20 | AllyStar |
| 21 | ExternalAHRS |
| 22 | DroneCAN-MovingBaseline-Base |
| 23 | DroneCAN-MovingBaseline-Rover |
| 24 | UnicoreNMEA |
| 25 | UnicoreMovingBaselineNMEA |
| 26 | Septentrio-DualAntenna(SBF) |
Bitmask for what GNSS system to use (all unchecked or zero to leave GPS as configured)
Controls how often the GPS should provide a position update. Lowering below 5Hz(default) is not allowed. Raising the rate above 5Hz usually provides little benefit and for some GPS (eg Ublox M9N) can severely impact performance.
| Value | Meaning |
|---|---|
| 100 | 10Hz |
| 125 | 8Hz |
| 200 | 5Hz |
X position of the first GPS antenna in body frame. Positive X is forward of the origin. Use antenna phase centroid location if provided by the manufacturer.
Y position of the first GPS antenna in body frame. Positive Y is to the right of the origin. Use antenna phase centroid location if provided by the manufacturer.
Z position of the first GPS antenna in body frame. Positive Z is down from the origin. Use antenna phase centroid location if provided by the manufacturer.
Controls the amount of GPS measurement delay that the autopilot compensates for. Set to zero to use the default delay for the detected GPS type.
The physical COM port on the connected device, currently only applies to SBF and GSOF GPS
| Value | Meaning |
|---|---|
| 0 | COM1(RS232) on GSOF |
| 1 | COM2(TTL) on GSOF |
GPS Node id for GPS. Detected node unless CAN_OVRIDE is set
GPS Node id for GPS. If 0 the gps will be automatically selected on a first-come-first-GPS basis.
Controls the type of moving base used if using moving base.This is renamed in 4.6 and later to GPSx_MB_TYPE.
| Value | Meaning |
|---|---|
| 0 | Relative to alternate GPS instance |
| 1 | RelativeToCustomBase |
X position of the base (primary) GPS antenna in body frame from the position of the 2nd antenna. Positive X is forward of the 2nd antenna. Use antenna phase centroid location if provided by the manufacturer.This is renamed in 4.6 and later to GPSx_MB_OFS_X.
Y position of the base (primary) GPS antenna in body frame from the position of the 2nd antenna. Positive Y is to the right of the 2nd antenna. Use antenna phase centroid location if provided by the manufacturer.This is renamed in 4.6 and later to GPSx_MB_OFS_Y.
Z position of the base (primary) GPS antenna in body frame from the position of the 2nd antenna. Positive Z is down from the 2nd antenna. Use antenna phase centroid location if provided by the manufacturer.This is renamed in 4.6 and later to GPSx_MB_OFS_Z.
GPS type
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | AUTO |
| 2 | uBlox |
| 5 | NMEA |
| 6 | SiRF |
| 7 | HIL |
| 8 | SwiftNav |
| 9 | DroneCAN |
| 10 | Septentrio(SBF) |
| 11 | Trimble(GSOF) |
| 13 | ERB |
| 14 | MAVLink |
| 15 | NOVA |
| 16 | HemisphereNMEA |
| 17 | uBlox-MovingBaseline-Base |
| 18 | uBlox-MovingBaseline-Rover |
| 19 | MSP |
| 20 | AllyStar |
| 21 | ExternalAHRS |
| 22 | DroneCAN-MovingBaseline-Base |
| 23 | DroneCAN-MovingBaseline-Rover |
| 24 | UnicoreNMEA |
| 25 | UnicoreMovingBaselineNMEA |
| 26 | Septentrio-DualAntenna(SBF) |
Bitmask for what GNSS system to use (all unchecked or zero to leave GPS as configured)
Controls how often the GPS should provide a position update. Lowering below 5Hz(default) is not allowed. Raising the rate above 5Hz usually provides little benefit and for some GPS (eg Ublox M9N) can severely impact performance.
| Value | Meaning |
|---|---|
| 100 | 10Hz |
| 125 | 8Hz |
| 200 | 5Hz |
X position of the first GPS antenna in body frame. Positive X is forward of the origin. Use antenna phase centroid location if provided by the manufacturer.
Y position of the first GPS antenna in body frame. Positive Y is to the right of the origin. Use antenna phase centroid location if provided by the manufacturer.
Z position of the first GPS antenna in body frame. Positive Z is down from the origin. Use antenna phase centroid location if provided by the manufacturer.
Controls the amount of GPS measurement delay that the autopilot compensates for. Set to zero to use the default delay for the detected GPS type.
The physical COM port on the connected device, currently only applies to SBF and GSOF GPS
| Value | Meaning |
|---|---|
| 0 | COM1(RS232) on GSOF |
| 1 | COM2(TTL) on GSOF |
GPS Node id for GPS. Detected node unless CAN_OVRIDE is set
GPS Node id for GPS. If 0 the gps will be automatically selected on a first-come-first-GPS basis.
Controls the type of moving base used if using moving base.This is renamed in 4.6 and later to GPSx_MB_TYPE.
| Value | Meaning |
|---|---|
| 0 | Relative to alternate GPS instance |
| 1 | RelativeToCustomBase |
X position of the base (primary) GPS antenna in body frame from the position of the 2nd antenna. Positive X is forward of the 2nd antenna. Use antenna phase centroid location if provided by the manufacturer.This is renamed in 4.6 and later to GPSx_MB_OFS_X.
Y position of the base (primary) GPS antenna in body frame from the position of the 2nd antenna. Positive Y is to the right of the 2nd antenna. Use antenna phase centroid location if provided by the manufacturer.This is renamed in 4.6 and later to GPSx_MB_OFS_Y.
Z position of the base (primary) GPS antenna in body frame from the position of the 2nd antenna. Positive Z is down from the 2nd antenna. Use antenna phase centroid location if provided by the manufacturer.This is renamed in 4.6 and later to GPSx_MB_OFS_Z.
Controls the type of moving base used if using moving base.This is renamed in 4.6 and later to GPSx_MB_TYPE.
| Value | Meaning |
|---|---|
| 0 | Relative to alternate GPS instance |
| 1 | RelativeToCustomBase |
X position of the base (primary) GPS antenna in body frame from the position of the 2nd antenna. Positive X is forward of the 2nd antenna. Use antenna phase centroid location if provided by the manufacturer.This is renamed in 4.6 and later to GPSx_MB_OFS_X.
Y position of the base (primary) GPS antenna in body frame from the position of the 2nd antenna. Positive Y is to the right of the 2nd antenna. Use antenna phase centroid location if provided by the manufacturer.This is renamed in 4.6 and later to GPSx_MB_OFS_Y.
Z position of the base (primary) GPS antenna in body frame from the position of the 2nd antenna. Positive Z is down from the 2nd antenna. Use antenna phase centroid location if provided by the manufacturer.This is renamed in 4.6 and later to GPSx_MB_OFS_Z.
Controls the type of moving base used if using moving base.This is renamed in 4.6 and later to GPSx_MB_TYPE.
| Value | Meaning |
|---|---|
| 0 | Relative to alternate GPS instance |
| 1 | RelativeToCustomBase |
X position of the base (primary) GPS antenna in body frame from the position of the 2nd antenna. Positive X is forward of the 2nd antenna. Use antenna phase centroid location if provided by the manufacturer.This is renamed in 4.6 and later to GPSx_MB_OFS_X.
Y position of the base (primary) GPS antenna in body frame from the position of the 2nd antenna. Positive Y is to the right of the 2nd antenna. Use antenna phase centroid location if provided by the manufacturer.This is renamed in 4.6 and later to GPSx_MB_OFS_Y.
Z position of the base (primary) GPS antenna in body frame from the position of the 2nd antenna. Positive Z is down from the 2nd antenna. Use antenna phase centroid location if provided by the manufacturer.This is renamed in 4.6 and later to GPSx_MB_OFS_Z.
Gripper enable/disable
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
Gripper enable/disable
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Servo |
| 2 | EPM |
PWM value in microseconds sent to Gripper to initiate grabbing the cargo
PWM value in microseconds sent to Gripper to release the cargo
PWM value in microseconds sent to grabber when not grabbing or releasing
Time in seconds that EPM gripper will regrab the cargo to ensure grip has not weakened; 0 to disable
Refer to https://docs.zubax.com/opengrab_epm_v3#UAVCAN_interface
Time in seconds that gripper close the gripper after opening; 0 to disable
Gyro sensor offsets of X axis. This is setup on each boot during gyro calibrations
Gyro sensor offsets of Y axis. This is setup on each boot during gyro calibrations
Gyro sensor offsets of Z axis. This is setup on each boot during gyro calibrations
Gyro2 sensor offsets of X axis. This is setup on each boot during gyro calibrations
Gyro2 sensor offsets of Y axis. This is setup on each boot during gyro calibrations
Gyro2 sensor offsets of Z axis. This is setup on each boot during gyro calibrations
Gyro3 sensor offsets of X axis. This is setup on each boot during gyro calibrations
Gyro3 sensor offsets of Y axis. This is setup on each boot during gyro calibrations
Gyro3 sensor offsets of Z axis. This is setup on each boot during gyro calibrations
Accelerometer scaling of X axis. Calculated during acceleration calibration routine
Accelerometer scaling of Y axis Calculated during acceleration calibration routine
Accelerometer scaling of Z axis Calculated during acceleration calibration routine
Accelerometer offsets of X axis. This is setup using the acceleration calibration or level operations
Accelerometer offsets of Y axis. This is setup using the acceleration calibration or level operations
Accelerometer offsets of Z axis. This is setup using the acceleration calibration or level operations
Accelerometer2 scaling of X axis. Calculated during acceleration calibration routine
Accelerometer2 scaling of Y axis Calculated during acceleration calibration routine
Accelerometer2 scaling of Z axis Calculated during acceleration calibration routine
Accelerometer2 offsets of X axis. This is setup using the acceleration calibration or level operations
Accelerometer2 offsets of Y axis. This is setup using the acceleration calibration or level operations
Accelerometer2 offsets of Z axis. This is setup using the acceleration calibration or level operations
Accelerometer3 scaling of X axis. Calculated during acceleration calibration routine
Accelerometer3 scaling of Y axis Calculated during acceleration calibration routine
Accelerometer3 scaling of Z axis Calculated during acceleration calibration routine
Accelerometer3 offsets of X axis. This is setup using the acceleration calibration or level operations
Accelerometer3 offsets of Y axis. This is setup using the acceleration calibration or level operations
Accelerometer3 offsets of Z axis. This is setup using the acceleration calibration or level operations
Filter cutoff frequency for gyroscopes. This can be set to a lower value to try to cope with very high vibration levels in aircraft. A value of zero means no filtering (not recommended!)
Filter cutoff frequency for accelerometers. This can be set to a lower value to try to cope with very high vibration levels in aircraft. A value of zero means no filtering (not recommended!)
Use first IMU for attitude, velocity and position estimates
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
Use second IMU for attitude, velocity and position estimates
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
Use third IMU for attitude, velocity and position estimates
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
Threshold to tolerate vibration to determine if vehicle is motionless. This depends on the frame type and if there is a constant vibration due to motors before launch or after landing. Total motionless is about 0.05. Suggested values: Planes/rover use 0.1, multirotors use 1, tradHeli uses 5
Conrols when automatic gyro calibration is performed
| Value | Meaning |
|---|---|
| 0 | Never |
| 1 | Start-up only |
Specifies how the accel cal routine determines the trims
| Value | Meaning |
|---|---|
| 0 | Don't adjust the trims |
| 1 | Assume first orientation was level |
| 2 | Assume ACC_BODYFIX is perfectly aligned to the vehicle |
The body-fixed accelerometer to be used for trim calculation
| Value | Meaning |
|---|---|
| 1 | IMU 1 |
| 2 | IMU 2 |
| 3 | IMU 3 |
X position of the first IMU Accelerometer in body frame. Positive X is forward of the origin. Attention: The IMU should be located as close to the vehicle c.g. as practical so that the value of this parameter is minimised. Failure to do so can result in noisy navigation velocity measurements due to vibration and IMU gyro noise. If the IMU cannot be moved and velocity noise is a problem, a location closer to the IMU can be used as the body frame origin.
Y position of the first IMU accelerometer in body frame. Positive Y is to the right of the origin. Attention: The IMU should be located as close to the vehicle c.g. as practical so that the value of this parameter is minimised. Failure to do so can result in noisy navigation velocity measurements due to vibration and IMU gyro noise. If the IMU cannot be moved and velocity noise is a problem, a location closer to the IMU can be used as the body frame origin.
Z position of the first IMU accelerometer in body frame. Positive Z is down from the origin. Attention: The IMU should be located as close to the vehicle c.g. as practical so that the value of this parameter is minimised. Failure to do so can result in noisy navigation velocity measurements due to vibration and IMU gyro noise. If the IMU cannot be moved and velocity noise is a problem, a location closer to the IMU can be used as the body frame origin.
X position of the second IMU accelerometer in body frame. Positive X is forward of the origin. Attention: The IMU should be located as close to the vehicle c.g. as practical so that the value of this parameter is minimised. Failure to do so can result in noisy navigation velocity measurements due to vibration and IMU gyro noise. If the IMU cannot be moved and velocity noise is a problem, a location closer to the IMU can be used as the body frame origin.
Y position of the second IMU accelerometer in body frame. Positive Y is to the right of the origin. Attention: The IMU should be located as close to the vehicle c.g. as practical so that the value of this parameter is minimised. Failure to do so can result in noisy navigation velocity measurements due to vibration and IMU gyro noise. If the IMU cannot be moved and velocity noise is a problem, a location closer to the IMU can be used as the body frame origin.
Z position of the second IMU accelerometer in body frame. Positive Z is down from the origin. Attention: The IMU should be located as close to the vehicle c.g. as practical so that the value of this parameter is minimised. Failure to do so can result in noisy navigation velocity measurements due to vibration and IMU gyro noise. If the IMU cannot be moved and velocity noise is a problem, a location closer to the IMU can be used as the body frame origin.
X position of the third IMU accelerometer in body frame. Positive X is forward of the origin. Attention: The IMU should be located as close to the vehicle c.g. as practical so that the value of this parameter is minimised. Failure to do so can result in noisy navigation velocity measurements due to vibration and IMU gyro noise. If the IMU cannot be moved and velocity noise is a problem, a location closer to the IMU can be used as the body frame origin.
Y position of the third IMU accelerometer in body frame. Positive Y is to the right of the origin. Attention: The IMU should be located as close to the vehicle c.g. as practical so that the value of this parameter is minimised. Failure to do so can result in noisy navigation velocity measurements due to vibration and IMU gyro noise. If the IMU cannot be moved and velocity noise is a problem, a location closer to the IMU can be used as the body frame origin.
Z position of the third IMU accelerometer in body frame. Positive Z is down from the origin. Attention: The IMU should be located as close to the vehicle c.g. as practical so that the value of this parameter is minimised. Failure to do so can result in noisy navigation velocity measurements due to vibration and IMU gyro noise. If the IMU cannot be moved and velocity noise is a problem, a location closer to the IMU can be used as the body frame origin.
Gyro sensor ID, taking into account its type, bus and instance
Gyro2 sensor ID, taking into account its type, bus and instance
Gyro3 sensor ID, taking into account its type, bus and instance
Accelerometer sensor ID, taking into account its type, bus and instance
Accelerometer2 sensor ID, taking into account its type, bus and instance
Accelerometer3 sensor ID, taking into account its type, bus and instance
Mask of IMUs to enable fast sampling on, if available
Bitmask of IMUs to enable. It can be used to prevent startup of specific detected IMUs
Gyro rate for IMUs with fast sampling enabled. The gyro rate is the sample rate at which the IMU filters operate and needs to be at least double the maximum filter frequency. If the sensor does not support the selected rate the next highest supported rate will be used. For IMUs which do not support fast sampling this setting is ignored and the default gyro rate of 1Khz is used.
| Value | Meaning |
|---|---|
| 0 | 1kHz |
| 1 | 2kHz |
| 2 | 4kHz |
| 3 | 8kHz |
Temperature that the 1st accelerometer was calibrated at
Temperature that the 1st gyroscope was calibrated at
Temperature that the 2nd accelerometer was calibrated at
Temperature that the 2nd gyroscope was calibrated at
Temperature that the 3rd accelerometer was calibrated at
Temperature that the 3rd gyroscope was calibrated at
This enables optional temperature calibration features. Setting of the Persist bits will save the temperature and/or accelerometer calibration parameters in the bootloader sector on the next update of the bootloader.
Raw logging options bitmask
Use first IMU for attitude, velocity and position estimates
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
Accelerometer sensor ID, taking into account its type, bus and instance
Accelerometer scaling of X axis. Calculated during acceleration calibration routine
Accelerometer scaling of Y axis Calculated during acceleration calibration routine
Accelerometer scaling of Z axis Calculated during acceleration calibration routine
Accelerometer offsets of X axis. This is setup using the acceleration calibration or level operations
Accelerometer offsets of Y axis. This is setup using the acceleration calibration or level operations
Accelerometer offsets of Z axis. This is setup using the acceleration calibration or level operations
X position of the first IMU Accelerometer in body frame. Positive X is forward of the origin. Attention: The IMU should be located as close to the vehicle c.g. as practical so that the value of this parameter is minimised. Failure to do so can result in noisy navigation velocity measurements due to vibration and IMU gyro noise. If the IMU cannot be moved and velocity noise is a problem, a location closer to the IMU can be used as the body frame origin.
Y position of the first IMU accelerometer in body frame. Positive Y is to the right of the origin. Attention: The IMU should be located as close to the vehicle c.g. as practical so that the value of this parameter is minimised. Failure to do so can result in noisy navigation velocity measurements due to vibration and IMU gyro noise. If the IMU cannot be moved and velocity noise is a problem, a location closer to the IMU can be used as the body frame origin.
Z position of the first IMU accelerometer in body frame. Positive Z is down from the origin. Attention: The IMU should be located as close to the vehicle c.g. as practical so that the value of this parameter is minimised. Failure to do so can result in noisy navigation velocity measurements due to vibration and IMU gyro noise. If the IMU cannot be moved and velocity noise is a problem, a location closer to the IMU can be used as the body frame origin.
Temperature that the accelerometer was calibrated at
Gyro sensor ID, taking into account its type, bus and instance
Gyro sensor offsets of X axis. This is setup on each boot during gyro calibrations
Gyro sensor offsets of Y axis. This is setup on each boot during gyro calibrations
Gyro sensor offsets of Z axis. This is setup on each boot during gyro calibrations
Temperature that the gyroscope was calibrated at
Enable the use of temperature calibration parameters for this IMU. For automatic learning set to 2 and also set the INS_TCALn_TMAX to the target temperature, then reboot
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
| 2 | LearnCalibration |
The minimum temperature that the calibration is valid for
The maximum temperature that the calibration is valid for. This must be at least 10 degrees above TMIN for calibration
This is the 1st order temperature coefficient from a temperature calibration
This is the 1st order temperature coefficient from a temperature calibration
This is the 1st order temperature coefficient from a temperature calibration
This is the 2nd order temperature coefficient from a temperature calibration
This is the 2nd order temperature coefficient from a temperature calibration
This is the 2nd order temperature coefficient from a temperature calibration
This is the 3rd order temperature coefficient from a temperature calibration
This is the 3rd order temperature coefficient from a temperature calibration
This is the 3rd order temperature coefficient from a temperature calibration
This is the 1st order temperature coefficient from a temperature calibration
This is the 1st order temperature coefficient from a temperature calibration
This is the 1st order temperature coefficient from a temperature calibration
This is the 2nd order temperature coefficient from a temperature calibration
This is the 2nd order temperature coefficient from a temperature calibration
This is the 2nd order temperature coefficient from a temperature calibration
This is the 3rd order temperature coefficient from a temperature calibration
This is the 3rd order temperature coefficient from a temperature calibration
This is the 3rd order temperature coefficient from a temperature calibration
Use first IMU for attitude, velocity and position estimates
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
Accelerometer sensor ID, taking into account its type, bus and instance
Accelerometer scaling of X axis. Calculated during acceleration calibration routine
Accelerometer scaling of Y axis Calculated during acceleration calibration routine
Accelerometer scaling of Z axis Calculated during acceleration calibration routine
Accelerometer offsets of X axis. This is setup using the acceleration calibration or level operations
Accelerometer offsets of Y axis. This is setup using the acceleration calibration or level operations
Accelerometer offsets of Z axis. This is setup using the acceleration calibration or level operations
X position of the first IMU Accelerometer in body frame. Positive X is forward of the origin. Attention: The IMU should be located as close to the vehicle c.g. as practical so that the value of this parameter is minimised. Failure to do so can result in noisy navigation velocity measurements due to vibration and IMU gyro noise. If the IMU cannot be moved and velocity noise is a problem, a location closer to the IMU can be used as the body frame origin.
Y position of the first IMU accelerometer in body frame. Positive Y is to the right of the origin. Attention: The IMU should be located as close to the vehicle c.g. as practical so that the value of this parameter is minimised. Failure to do so can result in noisy navigation velocity measurements due to vibration and IMU gyro noise. If the IMU cannot be moved and velocity noise is a problem, a location closer to the IMU can be used as the body frame origin.
Z position of the first IMU accelerometer in body frame. Positive Z is down from the origin. Attention: The IMU should be located as close to the vehicle c.g. as practical so that the value of this parameter is minimised. Failure to do so can result in noisy navigation velocity measurements due to vibration and IMU gyro noise. If the IMU cannot be moved and velocity noise is a problem, a location closer to the IMU can be used as the body frame origin.
Temperature that the accelerometer was calibrated at
Gyro sensor ID, taking into account its type, bus and instance
Gyro sensor offsets of X axis. This is setup on each boot during gyro calibrations
Gyro sensor offsets of Y axis. This is setup on each boot during gyro calibrations
Gyro sensor offsets of Z axis. This is setup on each boot during gyro calibrations
Temperature that the gyroscope was calibrated at
Enable the use of temperature calibration parameters for this IMU. For automatic learning set to 2 and also set the INS_TCALn_TMAX to the target temperature, then reboot
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
| 2 | LearnCalibration |
The minimum temperature that the calibration is valid for
The maximum temperature that the calibration is valid for. This must be at least 10 degrees above TMIN for calibration
This is the 1st order temperature coefficient from a temperature calibration
This is the 1st order temperature coefficient from a temperature calibration
This is the 1st order temperature coefficient from a temperature calibration
This is the 2nd order temperature coefficient from a temperature calibration
This is the 2nd order temperature coefficient from a temperature calibration
This is the 2nd order temperature coefficient from a temperature calibration
This is the 3rd order temperature coefficient from a temperature calibration
This is the 3rd order temperature coefficient from a temperature calibration
This is the 3rd order temperature coefficient from a temperature calibration
This is the 1st order temperature coefficient from a temperature calibration
This is the 1st order temperature coefficient from a temperature calibration
This is the 1st order temperature coefficient from a temperature calibration
This is the 2nd order temperature coefficient from a temperature calibration
This is the 2nd order temperature coefficient from a temperature calibration
This is the 2nd order temperature coefficient from a temperature calibration
This is the 3rd order temperature coefficient from a temperature calibration
This is the 3rd order temperature coefficient from a temperature calibration
This is the 3rd order temperature coefficient from a temperature calibration
Harmonic Notch Filter enable
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
Harmonic Notch Filter base center frequency in Hz. This is the center frequency for static notches, the center frequency for Throttle based notches at the reference thrust value, and the minimum limit of center frequency variation for all other notch types. This should always be set lower than half the backend gyro rate (which is typically 1Khz).
Harmonic Notch Filter bandwidth in Hz. This is typically set to half the base frequency. The ratio of base frequency to bandwidth determines the notch quality factor and is fixed across harmonics.
Harmonic Notch Filter attenuation in dB. Values greater than 40dB will typically produce a hard notch rather than a modest attenuation of motor noise.
Bitmask of harmonic frequencies to apply Harmonic Notch Filter to. This option takes effect on the next reboot. A value of 0 disables this filter. The first harmonic refers to the base frequency.
A reference value of zero disables dynamic updates on the Harmonic Notch Filter and a positive value enables dynamic updates on the Harmonic Notch Filter. For throttle-based scaling, this parameter is the reference value associated with the specified frequency to facilitate frequency scaling of the Harmonic Notch Filter. For RPM and ESC telemetry based tracking, this parameter is set to 1 to enable the Harmonic Notch Filter using the RPM sensor or ESC telemetry set to measure rotor speed. The sensor data is converted to Hz automatically for use in the Harmonic Notch Filter. This reference value may also be used to scale the sensor data, if required. For example, rpm sensor data is required to measure heli motor RPM. Therefore the reference value can be used to scale the RPM sensor to the rotor RPM.
Harmonic Notch Filter dynamic frequency tracking mode. Dynamic updates can be throttle, RPM sensor, ESC telemetry or dynamic FFT based. Throttle-based harmonic notch cannot be used on fixed wing only planes. It can for Copters, QuaadPlane(while in VTOL modes), and Rovers.
| Value | Meaning |
|---|---|
| 0 | Fixed |
| 1 | Throttle |
| 2 | RPM Sensor |
| 3 | ESC Telemetry |
| 4 | Dynamic FFT |
| 5 | Second RPM Sensor |
Harmonic Notch Filter options. Triple and double-notches can provide deeper attenuation across a wider bandwidth with reduced latency than single notches and are suitable for larger aircraft. Multi-Source attaches a harmonic notch to each detected noise frequency instead of simply being multiples of the base frequency, in the case of FFT it will attach notches to each of three detected noise peaks, in the case of ESC it will attach notches to each of four motor RPM values. Loop rate update changes the notch center frequency at the scheduler loop rate rather than at the default of 200Hz. If both double and triple notches are specified only double notches will take effect.
The minimum ratio below the configured frequency to take throttle based notch filters when flying at a throttle level below the reference throttle. Note that lower frequency notch filters will have more phase lag. If you want throttle based notch filtering to be effective at a throttle up to 30% below the configured notch frequency then set this parameter to 0.7. The default of 1.0 means the notch will not go below the frequency in the FREQ parameter.
Harmonic Notch Filter enable
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
Harmonic Notch Filter base center frequency in Hz. This is the center frequency for static notches, the center frequency for Throttle based notches at the reference thrust value, and the minimum limit of center frequency variation for all other notch types. This should always be set lower than half the backend gyro rate (which is typically 1Khz).
Harmonic Notch Filter bandwidth in Hz. This is typically set to half the base frequency. The ratio of base frequency to bandwidth determines the notch quality factor and is fixed across harmonics.
Harmonic Notch Filter attenuation in dB. Values greater than 40dB will typically produce a hard notch rather than a modest attenuation of motor noise.
Bitmask of harmonic frequencies to apply Harmonic Notch Filter to. This option takes effect on the next reboot. A value of 0 disables this filter. The first harmonic refers to the base frequency.
A reference value of zero disables dynamic updates on the Harmonic Notch Filter and a positive value enables dynamic updates on the Harmonic Notch Filter. For throttle-based scaling, this parameter is the reference value associated with the specified frequency to facilitate frequency scaling of the Harmonic Notch Filter. For RPM and ESC telemetry based tracking, this parameter is set to 1 to enable the Harmonic Notch Filter using the RPM sensor or ESC telemetry set to measure rotor speed. The sensor data is converted to Hz automatically for use in the Harmonic Notch Filter. This reference value may also be used to scale the sensor data, if required. For example, rpm sensor data is required to measure heli motor RPM. Therefore the reference value can be used to scale the RPM sensor to the rotor RPM.
Harmonic Notch Filter dynamic frequency tracking mode. Dynamic updates can be throttle, RPM sensor, ESC telemetry or dynamic FFT based. Throttle-based harmonic notch cannot be used on fixed wing only planes. It can for Copters, QuaadPlane(while in VTOL modes), and Rovers.
| Value | Meaning |
|---|---|
| 0 | Fixed |
| 1 | Throttle |
| 2 | RPM Sensor |
| 3 | ESC Telemetry |
| 4 | Dynamic FFT |
| 5 | Second RPM Sensor |
Harmonic Notch Filter options. Triple and double-notches can provide deeper attenuation across a wider bandwidth with reduced latency than single notches and are suitable for larger aircraft. Multi-Source attaches a harmonic notch to each detected noise frequency instead of simply being multiples of the base frequency, in the case of FFT it will attach notches to each of three detected noise peaks, in the case of ESC it will attach notches to each of four motor RPM values. Loop rate update changes the notch center frequency at the scheduler loop rate rather than at the default of 200Hz. If both double and triple notches are specified only double notches will take effect.
The minimum ratio below the configured frequency to take throttle based notch filters when flying at a throttle level below the reference throttle. Note that lower frequency notch filters will have more phase lag. If you want throttle based notch filtering to be effective at a throttle up to 30% below the configured notch frequency then set this parameter to 0.7. The default of 1.0 means the notch will not go below the frequency in the FREQ parameter.
Harmonic Notch Filter enable
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
Harmonic Notch Filter base center frequency in Hz. This is the center frequency for static notches, the center frequency for Throttle based notches at the reference thrust value, and the minimum limit of center frequency variation for all other notch types. This should always be set lower than half the backend gyro rate (which is typically 1Khz).
Harmonic Notch Filter bandwidth in Hz. This is typically set to half the base frequency. The ratio of base frequency to bandwidth determines the notch quality factor and is fixed across harmonics.
Harmonic Notch Filter attenuation in dB. Values greater than 40dB will typically produce a hard notch rather than a modest attenuation of motor noise.
Bitmask of harmonic frequencies to apply Harmonic Notch Filter to. This option takes effect on the next reboot. A value of 0 disables this filter. The first harmonic refers to the base frequency.
A reference value of zero disables dynamic updates on the Harmonic Notch Filter and a positive value enables dynamic updates on the Harmonic Notch Filter. For throttle-based scaling, this parameter is the reference value associated with the specified frequency to facilitate frequency scaling of the Harmonic Notch Filter. For RPM and ESC telemetry based tracking, this parameter is set to 1 to enable the Harmonic Notch Filter using the RPM sensor or ESC telemetry set to measure rotor speed. The sensor data is converted to Hz automatically for use in the Harmonic Notch Filter. This reference value may also be used to scale the sensor data, if required. For example, rpm sensor data is required to measure heli motor RPM. Therefore the reference value can be used to scale the RPM sensor to the rotor RPM.
Harmonic Notch Filter dynamic frequency tracking mode. Dynamic updates can be throttle, RPM sensor, ESC telemetry or dynamic FFT based. Throttle-based harmonic notch cannot be used on fixed wing only planes. It can for Copters, QuaadPlane(while in VTOL modes), and Rovers.
| Value | Meaning |
|---|---|
| 0 | Fixed |
| 1 | Throttle |
| 2 | RPM Sensor |
| 3 | ESC Telemetry |
| 4 | Dynamic FFT |
| 5 | Second RPM Sensor |
Harmonic Notch Filter options. Triple and double-notches can provide deeper attenuation across a wider bandwidth with reduced latency than single notches and are suitable for larger aircraft. Multi-Source attaches a harmonic notch to each detected noise frequency instead of simply being multiples of the base frequency, in the case of FFT it will attach notches to each of three detected noise peaks, in the case of ESC it will attach notches to each of four motor RPM values. Loop rate update changes the notch center frequency at the scheduler loop rate rather than at the default of 200Hz. If both double and triple notches are specified only double notches will take effect.
The minimum ratio below the configured frequency to take throttle based notch filters when flying at a throttle level below the reference throttle. Note that lower frequency notch filters will have more phase lag. If you want throttle based notch filtering to be effective at a throttle up to 30% below the configured notch frequency then set this parameter to 0.7. The default of 1.0 means the notch will not go below the frequency in the FREQ parameter.
Harmonic Notch Filter enable
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
Harmonic Notch Filter base center frequency in Hz. This is the center frequency for static notches, the center frequency for Throttle based notches at the reference thrust value, and the minimum limit of center frequency variation for all other notch types. This should always be set lower than half the backend gyro rate (which is typically 1Khz).
Harmonic Notch Filter bandwidth in Hz. This is typically set to half the base frequency. The ratio of base frequency to bandwidth determines the notch quality factor and is fixed across harmonics.
Harmonic Notch Filter attenuation in dB. Values greater than 40dB will typically produce a hard notch rather than a modest attenuation of motor noise.
Bitmask of harmonic frequencies to apply Harmonic Notch Filter to. This option takes effect on the next reboot. A value of 0 disables this filter. The first harmonic refers to the base frequency.
A reference value of zero disables dynamic updates on the Harmonic Notch Filter and a positive value enables dynamic updates on the Harmonic Notch Filter. For throttle-based scaling, this parameter is the reference value associated with the specified frequency to facilitate frequency scaling of the Harmonic Notch Filter. For RPM and ESC telemetry based tracking, this parameter is set to 1 to enable the Harmonic Notch Filter using the RPM sensor or ESC telemetry set to measure rotor speed. The sensor data is converted to Hz automatically for use in the Harmonic Notch Filter. This reference value may also be used to scale the sensor data, if required. For example, rpm sensor data is required to measure heli motor RPM. Therefore the reference value can be used to scale the RPM sensor to the rotor RPM.
Harmonic Notch Filter dynamic frequency tracking mode. Dynamic updates can be throttle, RPM sensor, ESC telemetry or dynamic FFT based. Throttle-based harmonic notch cannot be used on fixed wing only planes. It can for Copters, QuaadPlane(while in VTOL modes), and Rovers.
| Value | Meaning |
|---|---|
| 0 | Fixed |
| 1 | Throttle |
| 2 | RPM Sensor |
| 3 | ESC Telemetry |
| 4 | Dynamic FFT |
| 5 | Second RPM Sensor |
Harmonic Notch Filter options. Triple and double-notches can provide deeper attenuation across a wider bandwidth with reduced latency than single notches and are suitable for larger aircraft. Multi-Source attaches a harmonic notch to each detected noise frequency instead of simply being multiples of the base frequency, in the case of FFT it will attach notches to each of three detected noise peaks, in the case of ESC it will attach notches to each of four motor RPM values. Loop rate update changes the notch center frequency at the scheduler loop rate rather than at the default of 200Hz. If both double and triple notches are specified only double notches will take effect.
The minimum ratio below the configured frequency to take throttle based notch filters when flying at a throttle level below the reference throttle. Note that lower frequency notch filters will have more phase lag. If you want throttle based notch filtering to be effective at a throttle up to 30% below the configured notch frequency then set this parameter to 0.7. The default of 1.0 means the notch will not go below the frequency in the FREQ parameter.
Number of samples to take when logging streams of IMU sensor readings. Will be rounded down to a multiple of 32. This option takes effect on the next reboot.
Bitmap of which IMUs to log batch data for. This option takes effect on the next reboot.
Options for the BatchSampler.
Interval between pushing samples to the AP_Logger log
Number of samples to push to count every INS_LOG_BAT_LGIN
Enable the use of temperature calibration parameters for this IMU. For automatic learning set to 2 and also set the INS_TCALn_TMAX to the target temperature, then reboot
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
| 2 | LearnCalibration |
The minimum temperature that the calibration is valid for
The maximum temperature that the calibration is valid for. This must be at least 10 degrees above TMIN for calibration
This is the 1st order temperature coefficient from a temperature calibration
This is the 1st order temperature coefficient from a temperature calibration
This is the 1st order temperature coefficient from a temperature calibration
This is the 2nd order temperature coefficient from a temperature calibration
This is the 2nd order temperature coefficient from a temperature calibration
This is the 2nd order temperature coefficient from a temperature calibration
This is the 3rd order temperature coefficient from a temperature calibration
This is the 3rd order temperature coefficient from a temperature calibration
This is the 3rd order temperature coefficient from a temperature calibration
This is the 1st order temperature coefficient from a temperature calibration
This is the 1st order temperature coefficient from a temperature calibration
This is the 1st order temperature coefficient from a temperature calibration
This is the 2nd order temperature coefficient from a temperature calibration
This is the 2nd order temperature coefficient from a temperature calibration
This is the 2nd order temperature coefficient from a temperature calibration
This is the 3rd order temperature coefficient from a temperature calibration
This is the 3rd order temperature coefficient from a temperature calibration
This is the 3rd order temperature coefficient from a temperature calibration
Enable the use of temperature calibration parameters for this IMU. For automatic learning set to 2 and also set the INS_TCALn_TMAX to the target temperature, then reboot
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
| 2 | LearnCalibration |
The minimum temperature that the calibration is valid for
The maximum temperature that the calibration is valid for. This must be at least 10 degrees above TMIN for calibration
This is the 1st order temperature coefficient from a temperature calibration
This is the 1st order temperature coefficient from a temperature calibration
This is the 1st order temperature coefficient from a temperature calibration
This is the 2nd order temperature coefficient from a temperature calibration
This is the 2nd order temperature coefficient from a temperature calibration
This is the 2nd order temperature coefficient from a temperature calibration
This is the 3rd order temperature coefficient from a temperature calibration
This is the 3rd order temperature coefficient from a temperature calibration
This is the 3rd order temperature coefficient from a temperature calibration
This is the 1st order temperature coefficient from a temperature calibration
This is the 1st order temperature coefficient from a temperature calibration
This is the 1st order temperature coefficient from a temperature calibration
This is the 2nd order temperature coefficient from a temperature calibration
This is the 2nd order temperature coefficient from a temperature calibration
This is the 2nd order temperature coefficient from a temperature calibration
This is the 3rd order temperature coefficient from a temperature calibration
This is the 3rd order temperature coefficient from a temperature calibration
This is the 3rd order temperature coefficient from a temperature calibration
Enable the use of temperature calibration parameters for this IMU. For automatic learning set to 2 and also set the INS_TCALn_TMAX to the target temperature, then reboot
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
| 2 | LearnCalibration |
The minimum temperature that the calibration is valid for
The maximum temperature that the calibration is valid for. This must be at least 10 degrees above TMIN for calibration
This is the 1st order temperature coefficient from a temperature calibration
This is the 1st order temperature coefficient from a temperature calibration
This is the 1st order temperature coefficient from a temperature calibration
This is the 2nd order temperature coefficient from a temperature calibration
This is the 2nd order temperature coefficient from a temperature calibration
This is the 2nd order temperature coefficient from a temperature calibration
This is the 3rd order temperature coefficient from a temperature calibration
This is the 3rd order temperature coefficient from a temperature calibration
This is the 3rd order temperature coefficient from a temperature calibration
This is the 1st order temperature coefficient from a temperature calibration
This is the 1st order temperature coefficient from a temperature calibration
This is the 1st order temperature coefficient from a temperature calibration
This is the 2nd order temperature coefficient from a temperature calibration
This is the 2nd order temperature coefficient from a temperature calibration
This is the 2nd order temperature coefficient from a temperature calibration
This is the 3rd order temperature coefficient from a temperature calibration
This is the 3rd order temperature coefficient from a temperature calibration
This is the 3rd order temperature coefficient from a temperature calibration
Sets the number of motor poles to calculate the correct RPM value
Bitmap of what Logger backend types to enable. Block-based logging is available on SITL and boards with dataflash chips. Multiple backends can be selected.
The File and Block backends use a buffer to store data before writing to the block device. Raising this value may reduce "gaps" in your SD card logging but increases memory usage. This buffer size may be reduced to free up available memory
If LOG_DISARMED is set to 1 then logging will be enabled at all times including when disarmed. Logging before arming can make for very large logfiles but can help a lot when tracking down startup issues and is necessary if logging of EKF replay data is selected via the LOG_REPLAY parameter. If LOG_DISARMED is set to 2, then logging will be enabled when disarmed, but not if a USB connection is detected. This can be used to prevent unwanted data logs being generated when the vehicle is connected via USB for log downloading or parameter changes. If LOG_DISARMED is set to 3 then logging will happen while disarmed, but if the vehicle never arms then the logs using the filesystem backend will be discarded on the next boot.
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
| 2 | Disabled on USB connection |
| 3 | Discard log on reboot if never armed |
If LOG_REPLAY is set to 1 then the EKF2 and EKF3 state estimators will log detailed information needed for diagnosing problems with the Kalman filter. LOG_DISARMED must be set to 1 or 2 or else the log will not contain the pre-flight data required for replay testing of the EKF's. It is suggested that you also raise LOG_FILE_BUFSIZE to give more buffer space for logging and use a high quality microSD card to ensure no sensor data is lost.
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
When set, the current log file is closed when the vehicle is disarmed. If LOG_DISARMED is set then a fresh log will be opened. Applies to the File and Block logging backends.
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
Maximum amount of memory to allocate to AP_Logger-over-mavlink
This controls the amount of time before failing writes to a log file cause the file to be closed and logging stopped.
Set this such that the free space is larger than your largest typical flight log
This sets the maximum rate that streaming log messages will be logged to the file backend. A value of zero means that rate limiting is disabled.
This sets the maximum rate that streaming log messages will be logged to the mavlink backend. A value of zero means that rate limiting is disabled.
This sets the maximum rate that streaming log messages will be logged to the block backend. A value of zero means that rate limiting is disabled.
This sets the maximum rate that streaming log messages will be logged to any backend when disarmed. A value of zero means that the normal backend rate limit is applied.
This sets the maximum number of log file that will be written on dataflash or sd card before starting to rotate log number. Limit is capped at 500 logs.
Allows setting an individual MAVLink system id for this vehicle to distinguish it from others on the same network.
This sets what MAVLink source system IDs are accepted for GCS failsafe handling, RC overrides and manual control. When MAV_GCS_SYSID_HI is less than MAV_GCS_SYSID then only this value is considered to be a GCS. When MAV_GCS_SYSID_HI is greater than or equal to MAV_GCS_SYSID then the range of values between MAV_GCS_SYSID and MAV_GCS_SYSID_HI (inclusive) are all treated as valid GCS MAVLink system IDs
Upper limit of MAVLink source system IDs considered to be from the GCS. When this is less than MAV_GCS_SYSID then only MAV_GCS_SYSID is used as GCS ID. When this is greater than or equal to MAV_GCS_SYSID then the range of values from MAV_GCS_SYSID to MAV_GCS_SYSID_HI (inclusive) is treated as a GCS ID.
Alters various behaviour of the MAVLink interface
The amount of time (in seconds) to delay radio telemetry to prevent an Xbee bricking on power up
MAVLink Stream rate of RAW_IMU, SCALED_IMU2, SCALED_IMU3, SCALED_PRESSURE, SCALED_PRESSURE2, SCALED_PRESSURE3 and AIRSPEED
MAVLink Stream rate of SYS_STATUS, POWER_STATUS, MCU_STATUS, MEMINFO, CURRENT_WAYPOINT, GPS_RAW_INT, GPS_RTK (if available), GPS2_RAW_INT (if available), GPS2_RTK (if available), NAV_CONTROLLER_OUTPUT, FENCE_STATUS, and GLOBAL_TARGET_POS_INT
MAVLink Stream rate of SERVO_OUTPUT_RAW and RC_CHANNELS
MAVLink Raw Control stream rate of SERVO_OUT
MAVLink Stream rate of GLOBAL_POSITION_INT and LOCAL_POSITION_NED
MAVLink Stream rate of ATTITUDE, SIMSTATE (SIM only), AHRS2, RPM, AOA_SSA, LANDING,ESC_TELEMETRY,EFI_STATUS, and PID_TUNING
MAVLink Stream rate of VFR_HUD
MAVLink Stream rate of AHRS, SYSTEM_TIME, WIND, RANGEFINDER, DISTANCE_SENSOR, TERRAIN_REQUEST, TERRAIN_REPORT, BATTERY2, GIMBAL_DEVICE_ATTITUDE_STATUS, OPTICAL_FLOW, MAG_CAL_REPORT, MAG_CAL_PROGRESS, EKF_STATUS_REPORT, VIBRATION, and BATTERY_STATUS
MAVLink Stream rate of PARAM_VALUE
MAVLink ADSB stream rate
Bitmask for configuring this telemetry channel. For having effect on all channels, set the relevant mask in all MAVx_OPTIONS parameters. Keep in mind that part of the flags may require a reboot to take action.
MAVLink Stream rate of RAW_IMU, SCALED_IMU2, SCALED_IMU3, SCALED_PRESSURE, SCALED_PRESSURE2, SCALED_PRESSURE3 and AIRSPEED
MAVLink Stream rate of SYS_STATUS, POWER_STATUS, MCU_STATUS, MEMINFO, CURRENT_WAYPOINT, GPS_RAW_INT, GPS_RTK (if available), GPS2_RAW_INT (if available), GPS2_RTK (if available), NAV_CONTROLLER_OUTPUT, FENCE_STATUS, and GLOBAL_TARGET_POS_INT
MAVLink Stream rate of SERVO_OUTPUT_RAW and RC_CHANNELS
MAVLink Raw Control stream rate of SERVO_OUT
MAVLink Stream rate of GLOBAL_POSITION_INT and LOCAL_POSITION_NED
MAVLink Stream rate of ATTITUDE, SIMSTATE (SIM only), AHRS2, RPM, AOA_SSA, LANDING,ESC_TELEMETRY,EFI_STATUS, and PID_TUNING
MAVLink Stream rate of VFR_HUD
MAVLink Stream rate of AHRS, SYSTEM_TIME, WIND, RANGEFINDER, DISTANCE_SENSOR, TERRAIN_REQUEST, TERRAIN_REPORT, BATTERY2, GIMBAL_DEVICE_ATTITUDE_STATUS, OPTICAL_FLOW, MAG_CAL_REPORT, MAG_CAL_PROGRESS, EKF_STATUS_REPORT, VIBRATION, and BATTERY_STATUS
MAVLink Stream rate of PARAM_VALUE
MAVLink ADSB stream rate
Bitmask for configuring this telemetry channel. For having effect on all channels, set the relevant mask in all MAVx_OPTIONS parameters. Keep in mind that part of the flags may require a reboot to take action.
MAVLink Stream rate of RAW_IMU, SCALED_IMU2, SCALED_IMU3, SCALED_PRESSURE, SCALED_PRESSURE2, SCALED_PRESSURE3 and AIRSPEED
MAVLink Stream rate of SYS_STATUS, POWER_STATUS, MCU_STATUS, MEMINFO, CURRENT_WAYPOINT, GPS_RAW_INT, GPS_RTK (if available), GPS2_RAW_INT (if available), GPS2_RTK (if available), NAV_CONTROLLER_OUTPUT, FENCE_STATUS, and GLOBAL_TARGET_POS_INT
MAVLink Stream rate of SERVO_OUTPUT_RAW and RC_CHANNELS
MAVLink Raw Control stream rate of SERVO_OUT
MAVLink Stream rate of GLOBAL_POSITION_INT and LOCAL_POSITION_NED
MAVLink Stream rate of ATTITUDE, SIMSTATE (SIM only), AHRS2, RPM, AOA_SSA, LANDING,ESC_TELEMETRY,EFI_STATUS, and PID_TUNING
MAVLink Stream rate of VFR_HUD
MAVLink Stream rate of AHRS, SYSTEM_TIME, WIND, RANGEFINDER, DISTANCE_SENSOR, TERRAIN_REQUEST, TERRAIN_REPORT, BATTERY2, GIMBAL_DEVICE_ATTITUDE_STATUS, OPTICAL_FLOW, MAG_CAL_REPORT, MAG_CAL_PROGRESS, EKF_STATUS_REPORT, VIBRATION, and BATTERY_STATUS
MAVLink Stream rate of PARAM_VALUE
MAVLink ADSB stream rate
Bitmask for configuring this telemetry channel. For having effect on all channels, set the relevant mask in all MAVx_OPTIONS parameters. Keep in mind that part of the flags may require a reboot to take action.
MAVLink Stream rate of RAW_IMU, SCALED_IMU2, SCALED_IMU3, SCALED_PRESSURE, SCALED_PRESSURE2, SCALED_PRESSURE3 and AIRSPEED
MAVLink Stream rate of SYS_STATUS, POWER_STATUS, MCU_STATUS, MEMINFO, CURRENT_WAYPOINT, GPS_RAW_INT, GPS_RTK (if available), GPS2_RAW_INT (if available), GPS2_RTK (if available), NAV_CONTROLLER_OUTPUT, FENCE_STATUS, and GLOBAL_TARGET_POS_INT
MAVLink Stream rate of SERVO_OUTPUT_RAW and RC_CHANNELS
MAVLink Raw Control stream rate of SERVO_OUT
MAVLink Stream rate of GLOBAL_POSITION_INT and LOCAL_POSITION_NED
MAVLink Stream rate of ATTITUDE, SIMSTATE (SIM only), AHRS2, RPM, AOA_SSA, LANDING,ESC_TELEMETRY,EFI_STATUS, and PID_TUNING
MAVLink Stream rate of VFR_HUD
MAVLink Stream rate of AHRS, SYSTEM_TIME, WIND, RANGEFINDER, DISTANCE_SENSOR, TERRAIN_REQUEST, TERRAIN_REPORT, BATTERY2, GIMBAL_DEVICE_ATTITUDE_STATUS, OPTICAL_FLOW, MAG_CAL_REPORT, MAG_CAL_PROGRESS, EKF_STATUS_REPORT, VIBRATION, and BATTERY_STATUS
MAVLink Stream rate of PARAM_VALUE
MAVLink ADSB stream rate
Bitmask for configuring this telemetry channel. For having effect on all channels, set the relevant mask in all MAVx_OPTIONS parameters. Keep in mind that part of the flags may require a reboot to take action.
MAVLink Stream rate of RAW_IMU, SCALED_IMU2, SCALED_IMU3, SCALED_PRESSURE, SCALED_PRESSURE2, SCALED_PRESSURE3 and AIRSPEED
MAVLink Stream rate of SYS_STATUS, POWER_STATUS, MCU_STATUS, MEMINFO, CURRENT_WAYPOINT, GPS_RAW_INT, GPS_RTK (if available), GPS2_RAW_INT (if available), GPS2_RTK (if available), NAV_CONTROLLER_OUTPUT, FENCE_STATUS, and GLOBAL_TARGET_POS_INT
MAVLink Stream rate of SERVO_OUTPUT_RAW and RC_CHANNELS
MAVLink Raw Control stream rate of SERVO_OUT
MAVLink Stream rate of GLOBAL_POSITION_INT and LOCAL_POSITION_NED
MAVLink Stream rate of ATTITUDE, SIMSTATE (SIM only), AHRS2, RPM, AOA_SSA, LANDING,ESC_TELEMETRY,EFI_STATUS, and PID_TUNING
MAVLink Stream rate of VFR_HUD
MAVLink Stream rate of AHRS, SYSTEM_TIME, WIND, RANGEFINDER, DISTANCE_SENSOR, TERRAIN_REQUEST, TERRAIN_REPORT, BATTERY2, GIMBAL_DEVICE_ATTITUDE_STATUS, OPTICAL_FLOW, MAG_CAL_REPORT, MAG_CAL_PROGRESS, EKF_STATUS_REPORT, VIBRATION, and BATTERY_STATUS
MAVLink Stream rate of PARAM_VALUE
MAVLink ADSB stream rate
Bitmask for configuring this telemetry channel. For having effect on all channels, set the relevant mask in all MAVx_OPTIONS parameters. Keep in mind that part of the flags may require a reboot to take action.
MAVLink Stream rate of RAW_IMU, SCALED_IMU2, SCALED_IMU3, SCALED_PRESSURE, SCALED_PRESSURE2, SCALED_PRESSURE3 and AIRSPEED
MAVLink Stream rate of SYS_STATUS, POWER_STATUS, MCU_STATUS, MEMINFO, CURRENT_WAYPOINT, GPS_RAW_INT, GPS_RTK (if available), GPS2_RAW_INT (if available), GPS2_RTK (if available), NAV_CONTROLLER_OUTPUT, FENCE_STATUS, and GLOBAL_TARGET_POS_INT
MAVLink Stream rate of SERVO_OUTPUT_RAW and RC_CHANNELS
MAVLink Raw Control stream rate of SERVO_OUT
MAVLink Stream rate of GLOBAL_POSITION_INT and LOCAL_POSITION_NED
MAVLink Stream rate of ATTITUDE, SIMSTATE (SIM only), AHRS2, RPM, AOA_SSA, LANDING,ESC_TELEMETRY,EFI_STATUS, and PID_TUNING
MAVLink Stream rate of VFR_HUD
MAVLink Stream rate of AHRS, SYSTEM_TIME, WIND, RANGEFINDER, DISTANCE_SENSOR, TERRAIN_REQUEST, TERRAIN_REPORT, BATTERY2, GIMBAL_DEVICE_ATTITUDE_STATUS, OPTICAL_FLOW, MAG_CAL_REPORT, MAG_CAL_PROGRESS, EKF_STATUS_REPORT, VIBRATION, and BATTERY_STATUS
MAVLink Stream rate of PARAM_VALUE
MAVLink ADSB stream rate
Bitmask for configuring this telemetry channel. For having effect on all channels, set the relevant mask in all MAVx_OPTIONS parameters. Keep in mind that part of the flags may require a reboot to take action.
MAVLink Stream rate of RAW_IMU, SCALED_IMU2, SCALED_IMU3, SCALED_PRESSURE, SCALED_PRESSURE2, SCALED_PRESSURE3 and AIRSPEED
MAVLink Stream rate of SYS_STATUS, POWER_STATUS, MCU_STATUS, MEMINFO, CURRENT_WAYPOINT, GPS_RAW_INT, GPS_RTK (if available), GPS2_RAW_INT (if available), GPS2_RTK (if available), NAV_CONTROLLER_OUTPUT, FENCE_STATUS, and GLOBAL_TARGET_POS_INT
MAVLink Stream rate of SERVO_OUTPUT_RAW and RC_CHANNELS
MAVLink Raw Control stream rate of SERVO_OUT
MAVLink Stream rate of GLOBAL_POSITION_INT and LOCAL_POSITION_NED
MAVLink Stream rate of ATTITUDE, SIMSTATE (SIM only), AHRS2, RPM, AOA_SSA, LANDING,ESC_TELEMETRY,EFI_STATUS, and PID_TUNING
MAVLink Stream rate of VFR_HUD
MAVLink Stream rate of AHRS, SYSTEM_TIME, WIND, RANGEFINDER, DISTANCE_SENSOR, TERRAIN_REQUEST, TERRAIN_REPORT, BATTERY2, GIMBAL_DEVICE_ATTITUDE_STATUS, OPTICAL_FLOW, MAG_CAL_REPORT, MAG_CAL_PROGRESS, EKF_STATUS_REPORT, VIBRATION, and BATTERY_STATUS
MAVLink Stream rate of PARAM_VALUE
MAVLink ADSB stream rate
Bitmask for configuring this telemetry channel. For having effect on all channels, set the relevant mask in all MAVx_OPTIONS parameters. Keep in mind that part of the flags may require a reboot to take action.
MAVLink Stream rate of RAW_IMU, SCALED_IMU2, SCALED_IMU3, SCALED_PRESSURE, SCALED_PRESSURE2, SCALED_PRESSURE3 and AIRSPEED
MAVLink Stream rate of SYS_STATUS, POWER_STATUS, MCU_STATUS, MEMINFO, CURRENT_WAYPOINT, GPS_RAW_INT, GPS_RTK (if available), GPS2_RAW_INT (if available), GPS2_RTK (if available), NAV_CONTROLLER_OUTPUT, FENCE_STATUS, and GLOBAL_TARGET_POS_INT
MAVLink Stream rate of SERVO_OUTPUT_RAW and RC_CHANNELS
MAVLink Raw Control stream rate of SERVO_OUT
MAVLink Stream rate of GLOBAL_POSITION_INT and LOCAL_POSITION_NED
MAVLink Stream rate of ATTITUDE, SIMSTATE (SIM only), AHRS2, RPM, AOA_SSA, LANDING,ESC_TELEMETRY,EFI_STATUS, and PID_TUNING
MAVLink Stream rate of VFR_HUD
MAVLink Stream rate of AHRS, SYSTEM_TIME, WIND, RANGEFINDER, DISTANCE_SENSOR, TERRAIN_REQUEST, TERRAIN_REPORT, BATTERY2, GIMBAL_DEVICE_ATTITUDE_STATUS, OPTICAL_FLOW, MAG_CAL_REPORT, MAG_CAL_PROGRESS, EKF_STATUS_REPORT, VIBRATION, and BATTERY_STATUS
MAVLink Stream rate of PARAM_VALUE
MAVLink ADSB stream rate
Bitmask for configuring this telemetry channel. For having effect on all channels, set the relevant mask in all MAVx_OPTIONS parameters. Keep in mind that part of the flags may require a reboot to take action.
MAVLink Stream rate of RAW_IMU, SCALED_IMU2, SCALED_IMU3, SCALED_PRESSURE, SCALED_PRESSURE2, SCALED_PRESSURE3 and AIRSPEED
MAVLink Stream rate of SYS_STATUS, POWER_STATUS, MCU_STATUS, MEMINFO, CURRENT_WAYPOINT, GPS_RAW_INT, GPS_RTK (if available), GPS2_RAW_INT (if available), GPS2_RTK (if available), NAV_CONTROLLER_OUTPUT, FENCE_STATUS, and GLOBAL_TARGET_POS_INT
MAVLink Stream rate of SERVO_OUTPUT_RAW and RC_CHANNELS
MAVLink Raw Control stream rate of SERVO_OUT
MAVLink Stream rate of GLOBAL_POSITION_INT and LOCAL_POSITION_NED
MAVLink Stream rate of ATTITUDE, SIMSTATE (SIM only), AHRS2, RPM, AOA_SSA, LANDING,ESC_TELEMETRY,EFI_STATUS, and PID_TUNING
MAVLink Stream rate of VFR_HUD
MAVLink Stream rate of AHRS, SYSTEM_TIME, WIND, RANGEFINDER, DISTANCE_SENSOR, TERRAIN_REQUEST, TERRAIN_REPORT, BATTERY2, GIMBAL_DEVICE_ATTITUDE_STATUS, OPTICAL_FLOW, MAG_CAL_REPORT, MAG_CAL_PROGRESS, EKF_STATUS_REPORT, VIBRATION, and BATTERY_STATUS
MAVLink Stream rate of PARAM_VALUE
MAVLink ADSB stream rate
Bitmask for configuring this telemetry channel. For having effect on all channels, set the relevant mask in all MAVx_OPTIONS parameters. Keep in mind that part of the flags may require a reboot to take action.
MAVLink Stream rate of RAW_IMU, SCALED_IMU2, SCALED_IMU3, SCALED_PRESSURE, SCALED_PRESSURE2, SCALED_PRESSURE3 and AIRSPEED
MAVLink Stream rate of SYS_STATUS, POWER_STATUS, MCU_STATUS, MEMINFO, CURRENT_WAYPOINT, GPS_RAW_INT, GPS_RTK (if available), GPS2_RAW_INT (if available), GPS2_RTK (if available), NAV_CONTROLLER_OUTPUT, FENCE_STATUS, and GLOBAL_TARGET_POS_INT
MAVLink Stream rate of SERVO_OUTPUT_RAW and RC_CHANNELS
MAVLink Raw Control stream rate of SERVO_OUT
MAVLink Stream rate of GLOBAL_POSITION_INT and LOCAL_POSITION_NED
MAVLink Stream rate of ATTITUDE, SIMSTATE (SIM only), AHRS2, RPM, AOA_SSA, LANDING,ESC_TELEMETRY,EFI_STATUS, and PID_TUNING
MAVLink Stream rate of VFR_HUD
MAVLink Stream rate of AHRS, SYSTEM_TIME, WIND, RANGEFINDER, DISTANCE_SENSOR, TERRAIN_REQUEST, TERRAIN_REPORT, BATTERY2, GIMBAL_DEVICE_ATTITUDE_STATUS, OPTICAL_FLOW, MAG_CAL_REPORT, MAG_CAL_PROGRESS, EKF_STATUS_REPORT, VIBRATION, and BATTERY_STATUS
MAVLink Stream rate of PARAM_VALUE
MAVLink ADSB stream rate
Bitmask for configuring this telemetry channel. For having effect on all channels, set the relevant mask in all MAVx_OPTIONS parameters. Keep in mind that part of the flags may require a reboot to take action.
Used for average cell voltage calculation
| Value | Meaning |
|---|---|
| 0 | Auto |
| 1 | 1 |
| 2 | 2 |
| 3 | 3 |
| 4 | 4 |
| 5 | 5 |
| 6 | 6 |
| 7 | 7 |
| 8 | 8 |
| 9 | 9 |
| 10 | 10 |
| 11 | 11 |
| 12 | 12 |
| 13 | 13 |
| 14 | 14 |
A bitmask to set some MSP specific options: EnableTelemetryMode-allows "push" mode telemetry when only rx line of OSD ic connected to autopilot, EnableBTFLFonts-uses indexes corresponding to Betaflight fonts if OSD uses those instead of ArduPilot fonts. EnableINAVFonts uses INAV fonts and overrides EnableBTFLFonts if that option is enabled.
Networking Enable
| Value | Meaning |
|---|---|
| 0 | Disable |
| 1 | Enable |
Allows setting static subnet mask. The value is a count of consecutive bits. Examples: 24 = 255.255.255.0, 16 = 255.255.0.0
Enable/Disable DHCP client
| Value | Meaning |
|---|---|
| 0 | Disable |
| 1 | Enable |
Enable/Disable networking tests
Networking options
IPv4 address. Example: 192.xxx.xxx.xxx
IPv4 address. Example: xxx.168.xxx.xxx
IPv4 address. Example: xxx.xxx.144.xxx
IPv4 address. Example: xxx.xxx.xxx.14
IPv4 address. Example: 192.xxx.xxx.xxx
IPv4 address. Example: xxx.168.xxx.xxx
IPv4 address. Example: xxx.xxx.144.xxx
IPv4 address. Example: xxx.xxx.xxx.14
MAC address 1st byte
MAC address 2nd byte
MAC address 3rd byte
MAC address 4th byte
MAC address 5th byte
MAC address 6th byte
Port type for network serial port. For the two client types a valid destination IP address must be set. For the two server types either 0.0.0.0 or a local address can be used. The UDP client type will use broadcast if the IP is set to 255.255.255.255 and will use UDP multicast if the IP is in the multicast address range.
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | UDP client |
| 2 | UDP server |
| 3 | TCP client |
| 4 | TCP server |
Networked serial port protocol
| Value | Meaning |
|---|---|
| -1 | None |
| 1 | MAVLink1 |
| 2 | MAVLink2 |
| 3 | Frsky D |
| 4 | Frsky SPort |
| 5 | GPS |
| 7 | Alexmos Gimbal Serial |
| 8 | Gimbal |
| 9 | Rangefinder |
| 10 | FrSky SPort Passthrough (OpenTX) |
| 11 | Lidar360 |
| 13 | Beacon |
| 14 | Volz servo out |
| 15 | SBus servo out |
| 16 | ESC Telemetry |
| 17 | Devo Telemetry |
| 18 | OpticalFlow |
| 19 | RobotisServo |
| 20 | NMEA Output |
| 21 | WindVane |
| 22 | SLCAN |
| 23 | RCIN |
| 24 | EFI Serial |
| 25 | LTM |
| 26 | RunCam |
| 27 | HottTelem |
| 28 | Scripting |
| 29 | Crossfire VTX |
| 30 | Generator |
| 31 | Winch |
| 32 | MSP |
| 33 | DJI FPV |
| 34 | AirSpeed |
| 35 | ADSB |
| 36 | AHRS |
| 37 | SmartAudio |
| 38 | FETtecOneWire |
| 39 | Torqeedo |
| 40 | AIS |
| 41 | CoDevESC |
| 42 | DisplayPort |
| 43 | MAVLink High Latency |
| 44 | IRC Tramp |
| 45 | DDS XRCE |
| 46 | IMUDATA |
| 48 | PPP |
| 49 | i-BUS Telemetry |
| 50 | IOMCU |
Port number
IPv4 address. Example: 192.xxx.xxx.xxx
IPv4 address. Example: xxx.168.xxx.xxx
IPv4 address. Example: xxx.xxx.144.xxx
IPv4 address. Example: xxx.xxx.xxx.14
Port type for network serial port. For the two client types a valid destination IP address must be set. For the two server types either 0.0.0.0 or a local address can be used. The UDP client type will use broadcast if the IP is set to 255.255.255.255 and will use UDP multicast if the IP is in the multicast address range.
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | UDP client |
| 2 | UDP server |
| 3 | TCP client |
| 4 | TCP server |
Networked serial port protocol
| Value | Meaning |
|---|---|
| -1 | None |
| 1 | MAVLink1 |
| 2 | MAVLink2 |
| 3 | Frsky D |
| 4 | Frsky SPort |
| 5 | GPS |
| 7 | Alexmos Gimbal Serial |
| 8 | Gimbal |
| 9 | Rangefinder |
| 10 | FrSky SPort Passthrough (OpenTX) |
| 11 | Lidar360 |
| 13 | Beacon |
| 14 | Volz servo out |
| 15 | SBus servo out |
| 16 | ESC Telemetry |
| 17 | Devo Telemetry |
| 18 | OpticalFlow |
| 19 | RobotisServo |
| 20 | NMEA Output |
| 21 | WindVane |
| 22 | SLCAN |
| 23 | RCIN |
| 24 | EFI Serial |
| 25 | LTM |
| 26 | RunCam |
| 27 | HottTelem |
| 28 | Scripting |
| 29 | Crossfire VTX |
| 30 | Generator |
| 31 | Winch |
| 32 | MSP |
| 33 | DJI FPV |
| 34 | AirSpeed |
| 35 | ADSB |
| 36 | AHRS |
| 37 | SmartAudio |
| 38 | FETtecOneWire |
| 39 | Torqeedo |
| 40 | AIS |
| 41 | CoDevESC |
| 42 | DisplayPort |
| 43 | MAVLink High Latency |
| 44 | IRC Tramp |
| 45 | DDS XRCE |
| 46 | IMUDATA |
| 48 | PPP |
| 49 | i-BUS Telemetry |
| 50 | IOMCU |
Port number
IPv4 address. Example: 192.xxx.xxx.xxx
IPv4 address. Example: xxx.168.xxx.xxx
IPv4 address. Example: xxx.xxx.144.xxx
IPv4 address. Example: xxx.xxx.xxx.14
Port type for network serial port. For the two client types a valid destination IP address must be set. For the two server types either 0.0.0.0 or a local address can be used. The UDP client type will use broadcast if the IP is set to 255.255.255.255 and will use UDP multicast if the IP is in the multicast address range.
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | UDP client |
| 2 | UDP server |
| 3 | TCP client |
| 4 | TCP server |
Networked serial port protocol
| Value | Meaning |
|---|---|
| -1 | None |
| 1 | MAVLink1 |
| 2 | MAVLink2 |
| 3 | Frsky D |
| 4 | Frsky SPort |
| 5 | GPS |
| 7 | Alexmos Gimbal Serial |
| 8 | Gimbal |
| 9 | Rangefinder |
| 10 | FrSky SPort Passthrough (OpenTX) |
| 11 | Lidar360 |
| 13 | Beacon |
| 14 | Volz servo out |
| 15 | SBus servo out |
| 16 | ESC Telemetry |
| 17 | Devo Telemetry |
| 18 | OpticalFlow |
| 19 | RobotisServo |
| 20 | NMEA Output |
| 21 | WindVane |
| 22 | SLCAN |
| 23 | RCIN |
| 24 | EFI Serial |
| 25 | LTM |
| 26 | RunCam |
| 27 | HottTelem |
| 28 | Scripting |
| 29 | Crossfire VTX |
| 30 | Generator |
| 31 | Winch |
| 32 | MSP |
| 33 | DJI FPV |
| 34 | AirSpeed |
| 35 | ADSB |
| 36 | AHRS |
| 37 | SmartAudio |
| 38 | FETtecOneWire |
| 39 | Torqeedo |
| 40 | AIS |
| 41 | CoDevESC |
| 42 | DisplayPort |
| 43 | MAVLink High Latency |
| 44 | IRC Tramp |
| 45 | DDS XRCE |
| 46 | IMUDATA |
| 48 | PPP |
| 49 | i-BUS Telemetry |
| 50 | IOMCU |
Port number
IPv4 address. Example: 192.xxx.xxx.xxx
IPv4 address. Example: xxx.168.xxx.xxx
IPv4 address. Example: xxx.xxx.144.xxx
IPv4 address. Example: xxx.xxx.xxx.14
Port type for network serial port. For the two client types a valid destination IP address must be set. For the two server types either 0.0.0.0 or a local address can be used. The UDP client type will use broadcast if the IP is set to 255.255.255.255 and will use UDP multicast if the IP is in the multicast address range.
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | UDP client |
| 2 | UDP server |
| 3 | TCP client |
| 4 | TCP server |
Networked serial port protocol
| Value | Meaning |
|---|---|
| -1 | None |
| 1 | MAVLink1 |
| 2 | MAVLink2 |
| 3 | Frsky D |
| 4 | Frsky SPort |
| 5 | GPS |
| 7 | Alexmos Gimbal Serial |
| 8 | Gimbal |
| 9 | Rangefinder |
| 10 | FrSky SPort Passthrough (OpenTX) |
| 11 | Lidar360 |
| 13 | Beacon |
| 14 | Volz servo out |
| 15 | SBus servo out |
| 16 | ESC Telemetry |
| 17 | Devo Telemetry |
| 18 | OpticalFlow |
| 19 | RobotisServo |
| 20 | NMEA Output |
| 21 | WindVane |
| 22 | SLCAN |
| 23 | RCIN |
| 24 | EFI Serial |
| 25 | LTM |
| 26 | RunCam |
| 27 | HottTelem |
| 28 | Scripting |
| 29 | Crossfire VTX |
| 30 | Generator |
| 31 | Winch |
| 32 | MSP |
| 33 | DJI FPV |
| 34 | AirSpeed |
| 35 | ADSB |
| 36 | AHRS |
| 37 | SmartAudio |
| 38 | FETtecOneWire |
| 39 | Torqeedo |
| 40 | AIS |
| 41 | CoDevESC |
| 42 | DisplayPort |
| 43 | MAVLink High Latency |
| 44 | IRC Tramp |
| 45 | DDS XRCE |
| 46 | IMUDATA |
| 48 | PPP |
| 49 | i-BUS Telemetry |
| 50 | IOMCU |
Port number
IPv4 address. Example: 192.xxx.xxx.xxx
IPv4 address. Example: xxx.168.xxx.xxx
IPv4 address. Example: xxx.xxx.144.xxx
IPv4 address. Example: xxx.xxx.xxx.14
IPv4 address. Example: 192.xxx.xxx.xxx
IPv4 address. Example: xxx.168.xxx.xxx
IPv4 address. Example: xxx.xxx.144.xxx
IPv4 address. Example: xxx.xxx.xxx.14
IPv4 address. Example: 192.xxx.xxx.xxx
IPv4 address. Example: xxx.168.xxx.xxx
IPv4 address. Example: xxx.xxx.144.xxx
IPv4 address. Example: xxx.xxx.xxx.14
NMEA Output rate. This controls the interval at which all the enabled NMEA messages are sent. Most NMEA systems expect 100ms (10Hz) or slower.
This is a bitmask of enabled NMEA messages. All messages will be sent consecutively at the same rate interval
Select the RGB LED brightness level. When USB is connected brightness will never be higher than low regardless of the setting.
| Value | Meaning |
|---|---|
| 0 | Off |
| 1 | Low |
| 2 | Medium |
| 3 | High |
Controls what types of Buzzer will be enabled
Specifies the source for the colours and brightness for the LED. OutbackChallenge conforms to the MedicalExpress (https://uavchallenge.org/medical-express/) rules, essentially "Green" is disarmed (safe-to-approach), "Red" is armed (not safe-to-approach). Traffic light is a simplified color set, red when armed, yellow when the safety switch is not surpressing outputs (but disarmed), and green when outputs are surpressed and disarmed, the LED will blink faster if disarmed and failing arming checks.
| Value | Meaning |
|---|---|
| 0 | Standard |
| 1 | MAVLink/Scripting/AP_Periph |
| 2 | OutbackChallenge |
| 3 | TrafficLight |
This sets up the type of on-board I2C display. Disabled by default.
| Value | Meaning |
|---|---|
| 0 | Disable |
| 1 | ssd1306 |
| 2 | sh1106 |
| 10 | SITL |
Enable/Disable Solo Oreo LED driver, 0 to disable, 1 for Aircraft theme, 2 for Rover theme
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Aircraft |
| 2 | Rover |
Enables to connect active buzzer to arbitrary pin. Requires 3-pin buzzer or additional MOSFET! Some the Wiki's "GPIOs" page for how to determine the pin number for a given autopilot.
| Value | Meaning |
|---|---|
| -1 | Disabled |
Controls what types of LEDs will be enabled
Specifies pin level that indicates buzzer should play
| Value | Meaning |
|---|---|
| 0 | LowIsOn |
| 1 | HighIsOn |
Control the volume of the buzzer
The number of Serial LED's to use for notifications (NeoPixel's and ProfiLED)
Timeout after which RC overrides will no longer be used, and RC input will resume, 0 will disable RC overrides, -1 will never timeout, and continue using overrides until they are disabled
RC input options
Bitmask of enabled RC protocols. Allows narrowing the protocol detection to only specific types of RC receivers which can avoid issues with incorrect detection. Set to 1 to enable all protocols.
RC failsafe will trigger this many seconds after loss of RC
RC minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
RC trim (neutral) PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
RC maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse channel input. Set to 0 for normal operation. Set to 1 to reverse this input channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
PWM dead zone in microseconds around trim or bottom
Function assigned to this RC channel
| Value | Meaning |
|---|---|
| 0 | Do Nothing |
| 18 | LAND Mode |
| 46 | RC Override Enable |
| 65 | GPS Disable |
| 81 | Disarm |
| 90 | EKF Source Set |
| 100 | KillIMU1 |
| 101 | KillIMU2 |
| 103 | EKF lane switch attempt |
| 104 | EKF yaw reset |
| 110 | KillIMU3 |
| 111 | Loweheiser starter |
| 112 | SwitchExternalAHRS |
| 153 | ArmDisarm |
| 164 | Pause Stream Logging |
| 166 | Camera Record Video |
| 167 | Camera Zoom |
| 168 | Camera Manual Focus |
| 169 | Camera Auto Focus |
| 171 | Calibrate Compasses |
| 172 | Battery MPPT Enable |
| 174 | Camera Image Tracking |
| 175 | Camera Lens |
| 177 | Mount LRF enable |
| 218 | Loweheiser throttle |
| 300 | Scripting1 |
| 301 | Scripting2 |
| 302 | Scripting3 |
| 303 | Scripting4 |
| 304 | Scripting5 |
| 305 | Scripting6 |
| 306 | Scripting7 |
| 307 | Scripting8 |
| 308 | Scripting9 |
| 309 | Scripting10 |
| 310 | Scripting11 |
| 311 | Scripting12 |
| 312 | Scripting13 |
| 313 | Scripting14 |
| 314 | Scripting15 |
| 315 | Scripting16 |
| 316 | Stop-Restart Scripting |
RC minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
RC trim (neutral) PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
RC maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse channel input. Set to 0 for normal operation. Set to 1 to reverse this input channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
PWM dead zone in microseconds around trim or bottom
Function assigned to this RC channel
| Value | Meaning |
|---|---|
| 0 | Do Nothing |
| 18 | LAND Mode |
| 46 | RC Override Enable |
| 65 | GPS Disable |
| 81 | Disarm |
| 90 | EKF Source Set |
| 100 | KillIMU1 |
| 101 | KillIMU2 |
| 103 | EKF lane switch attempt |
| 104 | EKF yaw reset |
| 110 | KillIMU3 |
| 111 | Loweheiser starter |
| 112 | SwitchExternalAHRS |
| 153 | ArmDisarm |
| 164 | Pause Stream Logging |
| 166 | Camera Record Video |
| 167 | Camera Zoom |
| 168 | Camera Manual Focus |
| 169 | Camera Auto Focus |
| 171 | Calibrate Compasses |
| 172 | Battery MPPT Enable |
| 174 | Camera Image Tracking |
| 175 | Camera Lens |
| 177 | Mount LRF enable |
| 218 | Loweheiser throttle |
| 300 | Scripting1 |
| 301 | Scripting2 |
| 302 | Scripting3 |
| 303 | Scripting4 |
| 304 | Scripting5 |
| 305 | Scripting6 |
| 306 | Scripting7 |
| 307 | Scripting8 |
| 308 | Scripting9 |
| 309 | Scripting10 |
| 310 | Scripting11 |
| 311 | Scripting12 |
| 312 | Scripting13 |
| 313 | Scripting14 |
| 314 | Scripting15 |
| 315 | Scripting16 |
| 316 | Stop-Restart Scripting |
RC minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
RC trim (neutral) PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
RC maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse channel input. Set to 0 for normal operation. Set to 1 to reverse this input channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
PWM dead zone in microseconds around trim or bottom
Function assigned to this RC channel
| Value | Meaning |
|---|---|
| 0 | Do Nothing |
| 18 | LAND Mode |
| 46 | RC Override Enable |
| 65 | GPS Disable |
| 81 | Disarm |
| 90 | EKF Source Set |
| 100 | KillIMU1 |
| 101 | KillIMU2 |
| 103 | EKF lane switch attempt |
| 104 | EKF yaw reset |
| 110 | KillIMU3 |
| 111 | Loweheiser starter |
| 112 | SwitchExternalAHRS |
| 153 | ArmDisarm |
| 164 | Pause Stream Logging |
| 166 | Camera Record Video |
| 167 | Camera Zoom |
| 168 | Camera Manual Focus |
| 169 | Camera Auto Focus |
| 171 | Calibrate Compasses |
| 172 | Battery MPPT Enable |
| 174 | Camera Image Tracking |
| 175 | Camera Lens |
| 177 | Mount LRF enable |
| 218 | Loweheiser throttle |
| 300 | Scripting1 |
| 301 | Scripting2 |
| 302 | Scripting3 |
| 303 | Scripting4 |
| 304 | Scripting5 |
| 305 | Scripting6 |
| 306 | Scripting7 |
| 307 | Scripting8 |
| 308 | Scripting9 |
| 309 | Scripting10 |
| 310 | Scripting11 |
| 311 | Scripting12 |
| 312 | Scripting13 |
| 313 | Scripting14 |
| 314 | Scripting15 |
| 315 | Scripting16 |
| 316 | Stop-Restart Scripting |
RC minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
RC trim (neutral) PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
RC maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse channel input. Set to 0 for normal operation. Set to 1 to reverse this input channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
PWM dead zone in microseconds around trim or bottom
Function assigned to this RC channel
| Value | Meaning |
|---|---|
| 0 | Do Nothing |
| 18 | LAND Mode |
| 46 | RC Override Enable |
| 65 | GPS Disable |
| 81 | Disarm |
| 90 | EKF Source Set |
| 100 | KillIMU1 |
| 101 | KillIMU2 |
| 103 | EKF lane switch attempt |
| 104 | EKF yaw reset |
| 110 | KillIMU3 |
| 111 | Loweheiser starter |
| 112 | SwitchExternalAHRS |
| 153 | ArmDisarm |
| 164 | Pause Stream Logging |
| 166 | Camera Record Video |
| 167 | Camera Zoom |
| 168 | Camera Manual Focus |
| 169 | Camera Auto Focus |
| 171 | Calibrate Compasses |
| 172 | Battery MPPT Enable |
| 174 | Camera Image Tracking |
| 175 | Camera Lens |
| 177 | Mount LRF enable |
| 218 | Loweheiser throttle |
| 300 | Scripting1 |
| 301 | Scripting2 |
| 302 | Scripting3 |
| 303 | Scripting4 |
| 304 | Scripting5 |
| 305 | Scripting6 |
| 306 | Scripting7 |
| 307 | Scripting8 |
| 308 | Scripting9 |
| 309 | Scripting10 |
| 310 | Scripting11 |
| 311 | Scripting12 |
| 312 | Scripting13 |
| 313 | Scripting14 |
| 314 | Scripting15 |
| 315 | Scripting16 |
| 316 | Stop-Restart Scripting |
RC minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
RC trim (neutral) PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
RC maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse channel input. Set to 0 for normal operation. Set to 1 to reverse this input channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
PWM dead zone in microseconds around trim or bottom
Function assigned to this RC channel
| Value | Meaning |
|---|---|
| 0 | Do Nothing |
| 18 | LAND Mode |
| 46 | RC Override Enable |
| 65 | GPS Disable |
| 81 | Disarm |
| 90 | EKF Source Set |
| 100 | KillIMU1 |
| 101 | KillIMU2 |
| 103 | EKF lane switch attempt |
| 104 | EKF yaw reset |
| 110 | KillIMU3 |
| 111 | Loweheiser starter |
| 112 | SwitchExternalAHRS |
| 153 | ArmDisarm |
| 164 | Pause Stream Logging |
| 166 | Camera Record Video |
| 167 | Camera Zoom |
| 168 | Camera Manual Focus |
| 169 | Camera Auto Focus |
| 171 | Calibrate Compasses |
| 172 | Battery MPPT Enable |
| 174 | Camera Image Tracking |
| 175 | Camera Lens |
| 177 | Mount LRF enable |
| 218 | Loweheiser throttle |
| 300 | Scripting1 |
| 301 | Scripting2 |
| 302 | Scripting3 |
| 303 | Scripting4 |
| 304 | Scripting5 |
| 305 | Scripting6 |
| 306 | Scripting7 |
| 307 | Scripting8 |
| 308 | Scripting9 |
| 309 | Scripting10 |
| 310 | Scripting11 |
| 311 | Scripting12 |
| 312 | Scripting13 |
| 313 | Scripting14 |
| 314 | Scripting15 |
| 315 | Scripting16 |
| 316 | Stop-Restart Scripting |
RC minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
RC trim (neutral) PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
RC maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse channel input. Set to 0 for normal operation. Set to 1 to reverse this input channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
PWM dead zone in microseconds around trim or bottom
Function assigned to this RC channel
| Value | Meaning |
|---|---|
| 0 | Do Nothing |
| 18 | LAND Mode |
| 46 | RC Override Enable |
| 65 | GPS Disable |
| 81 | Disarm |
| 90 | EKF Source Set |
| 100 | KillIMU1 |
| 101 | KillIMU2 |
| 103 | EKF lane switch attempt |
| 104 | EKF yaw reset |
| 110 | KillIMU3 |
| 111 | Loweheiser starter |
| 112 | SwitchExternalAHRS |
| 153 | ArmDisarm |
| 164 | Pause Stream Logging |
| 166 | Camera Record Video |
| 167 | Camera Zoom |
| 168 | Camera Manual Focus |
| 169 | Camera Auto Focus |
| 171 | Calibrate Compasses |
| 172 | Battery MPPT Enable |
| 174 | Camera Image Tracking |
| 175 | Camera Lens |
| 177 | Mount LRF enable |
| 218 | Loweheiser throttle |
| 300 | Scripting1 |
| 301 | Scripting2 |
| 302 | Scripting3 |
| 303 | Scripting4 |
| 304 | Scripting5 |
| 305 | Scripting6 |
| 306 | Scripting7 |
| 307 | Scripting8 |
| 308 | Scripting9 |
| 309 | Scripting10 |
| 310 | Scripting11 |
| 311 | Scripting12 |
| 312 | Scripting13 |
| 313 | Scripting14 |
| 314 | Scripting15 |
| 315 | Scripting16 |
| 316 | Stop-Restart Scripting |
RC minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
RC trim (neutral) PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
RC maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse channel input. Set to 0 for normal operation. Set to 1 to reverse this input channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
PWM dead zone in microseconds around trim or bottom
Function assigned to this RC channel
| Value | Meaning |
|---|---|
| 0 | Do Nothing |
| 18 | LAND Mode |
| 46 | RC Override Enable |
| 65 | GPS Disable |
| 81 | Disarm |
| 90 | EKF Source Set |
| 100 | KillIMU1 |
| 101 | KillIMU2 |
| 103 | EKF lane switch attempt |
| 104 | EKF yaw reset |
| 110 | KillIMU3 |
| 111 | Loweheiser starter |
| 112 | SwitchExternalAHRS |
| 153 | ArmDisarm |
| 164 | Pause Stream Logging |
| 166 | Camera Record Video |
| 167 | Camera Zoom |
| 168 | Camera Manual Focus |
| 169 | Camera Auto Focus |
| 171 | Calibrate Compasses |
| 172 | Battery MPPT Enable |
| 174 | Camera Image Tracking |
| 175 | Camera Lens |
| 177 | Mount LRF enable |
| 218 | Loweheiser throttle |
| 300 | Scripting1 |
| 301 | Scripting2 |
| 302 | Scripting3 |
| 303 | Scripting4 |
| 304 | Scripting5 |
| 305 | Scripting6 |
| 306 | Scripting7 |
| 307 | Scripting8 |
| 308 | Scripting9 |
| 309 | Scripting10 |
| 310 | Scripting11 |
| 311 | Scripting12 |
| 312 | Scripting13 |
| 313 | Scripting14 |
| 314 | Scripting15 |
| 315 | Scripting16 |
| 316 | Stop-Restart Scripting |
RC minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
RC trim (neutral) PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
RC maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse channel input. Set to 0 for normal operation. Set to 1 to reverse this input channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
PWM dead zone in microseconds around trim or bottom
Function assigned to this RC channel
| Value | Meaning |
|---|---|
| 0 | Do Nothing |
| 18 | LAND Mode |
| 46 | RC Override Enable |
| 65 | GPS Disable |
| 81 | Disarm |
| 90 | EKF Source Set |
| 100 | KillIMU1 |
| 101 | KillIMU2 |
| 103 | EKF lane switch attempt |
| 104 | EKF yaw reset |
| 110 | KillIMU3 |
| 111 | Loweheiser starter |
| 112 | SwitchExternalAHRS |
| 153 | ArmDisarm |
| 164 | Pause Stream Logging |
| 166 | Camera Record Video |
| 167 | Camera Zoom |
| 168 | Camera Manual Focus |
| 169 | Camera Auto Focus |
| 171 | Calibrate Compasses |
| 172 | Battery MPPT Enable |
| 174 | Camera Image Tracking |
| 175 | Camera Lens |
| 177 | Mount LRF enable |
| 218 | Loweheiser throttle |
| 300 | Scripting1 |
| 301 | Scripting2 |
| 302 | Scripting3 |
| 303 | Scripting4 |
| 304 | Scripting5 |
| 305 | Scripting6 |
| 306 | Scripting7 |
| 307 | Scripting8 |
| 308 | Scripting9 |
| 309 | Scripting10 |
| 310 | Scripting11 |
| 311 | Scripting12 |
| 312 | Scripting13 |
| 313 | Scripting14 |
| 314 | Scripting15 |
| 315 | Scripting16 |
| 316 | Stop-Restart Scripting |
RC minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
RC trim (neutral) PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
RC maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse channel input. Set to 0 for normal operation. Set to 1 to reverse this input channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
PWM dead zone in microseconds around trim or bottom
Function assigned to this RC channel
| Value | Meaning |
|---|---|
| 0 | Do Nothing |
| 18 | LAND Mode |
| 46 | RC Override Enable |
| 65 | GPS Disable |
| 81 | Disarm |
| 90 | EKF Source Set |
| 100 | KillIMU1 |
| 101 | KillIMU2 |
| 103 | EKF lane switch attempt |
| 104 | EKF yaw reset |
| 110 | KillIMU3 |
| 111 | Loweheiser starter |
| 112 | SwitchExternalAHRS |
| 153 | ArmDisarm |
| 164 | Pause Stream Logging |
| 166 | Camera Record Video |
| 167 | Camera Zoom |
| 168 | Camera Manual Focus |
| 169 | Camera Auto Focus |
| 171 | Calibrate Compasses |
| 172 | Battery MPPT Enable |
| 174 | Camera Image Tracking |
| 175 | Camera Lens |
| 177 | Mount LRF enable |
| 218 | Loweheiser throttle |
| 300 | Scripting1 |
| 301 | Scripting2 |
| 302 | Scripting3 |
| 303 | Scripting4 |
| 304 | Scripting5 |
| 305 | Scripting6 |
| 306 | Scripting7 |
| 307 | Scripting8 |
| 308 | Scripting9 |
| 309 | Scripting10 |
| 310 | Scripting11 |
| 311 | Scripting12 |
| 312 | Scripting13 |
| 313 | Scripting14 |
| 314 | Scripting15 |
| 315 | Scripting16 |
| 316 | Stop-Restart Scripting |
RC minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
RC trim (neutral) PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
RC maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse channel input. Set to 0 for normal operation. Set to 1 to reverse this input channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
PWM dead zone in microseconds around trim or bottom
Function assigned to this RC channel
| Value | Meaning |
|---|---|
| 0 | Do Nothing |
| 18 | LAND Mode |
| 46 | RC Override Enable |
| 65 | GPS Disable |
| 81 | Disarm |
| 90 | EKF Source Set |
| 100 | KillIMU1 |
| 101 | KillIMU2 |
| 103 | EKF lane switch attempt |
| 104 | EKF yaw reset |
| 110 | KillIMU3 |
| 111 | Loweheiser starter |
| 112 | SwitchExternalAHRS |
| 153 | ArmDisarm |
| 164 | Pause Stream Logging |
| 166 | Camera Record Video |
| 167 | Camera Zoom |
| 168 | Camera Manual Focus |
| 169 | Camera Auto Focus |
| 171 | Calibrate Compasses |
| 172 | Battery MPPT Enable |
| 174 | Camera Image Tracking |
| 175 | Camera Lens |
| 177 | Mount LRF enable |
| 218 | Loweheiser throttle |
| 300 | Scripting1 |
| 301 | Scripting2 |
| 302 | Scripting3 |
| 303 | Scripting4 |
| 304 | Scripting5 |
| 305 | Scripting6 |
| 306 | Scripting7 |
| 307 | Scripting8 |
| 308 | Scripting9 |
| 309 | Scripting10 |
| 310 | Scripting11 |
| 311 | Scripting12 |
| 312 | Scripting13 |
| 313 | Scripting14 |
| 314 | Scripting15 |
| 315 | Scripting16 |
| 316 | Stop-Restart Scripting |
RC minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
RC trim (neutral) PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
RC maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse channel input. Set to 0 for normal operation. Set to 1 to reverse this input channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
PWM dead zone in microseconds around trim or bottom
Function assigned to this RC channel
| Value | Meaning |
|---|---|
| 0 | Do Nothing |
| 18 | LAND Mode |
| 46 | RC Override Enable |
| 65 | GPS Disable |
| 81 | Disarm |
| 90 | EKF Source Set |
| 100 | KillIMU1 |
| 101 | KillIMU2 |
| 103 | EKF lane switch attempt |
| 104 | EKF yaw reset |
| 110 | KillIMU3 |
| 111 | Loweheiser starter |
| 112 | SwitchExternalAHRS |
| 153 | ArmDisarm |
| 164 | Pause Stream Logging |
| 166 | Camera Record Video |
| 167 | Camera Zoom |
| 168 | Camera Manual Focus |
| 169 | Camera Auto Focus |
| 171 | Calibrate Compasses |
| 172 | Battery MPPT Enable |
| 174 | Camera Image Tracking |
| 175 | Camera Lens |
| 177 | Mount LRF enable |
| 218 | Loweheiser throttle |
| 300 | Scripting1 |
| 301 | Scripting2 |
| 302 | Scripting3 |
| 303 | Scripting4 |
| 304 | Scripting5 |
| 305 | Scripting6 |
| 306 | Scripting7 |
| 307 | Scripting8 |
| 308 | Scripting9 |
| 309 | Scripting10 |
| 310 | Scripting11 |
| 311 | Scripting12 |
| 312 | Scripting13 |
| 313 | Scripting14 |
| 314 | Scripting15 |
| 315 | Scripting16 |
| 316 | Stop-Restart Scripting |
RC minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
RC trim (neutral) PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
RC maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse channel input. Set to 0 for normal operation. Set to 1 to reverse this input channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
PWM dead zone in microseconds around trim or bottom
Function assigned to this RC channel
| Value | Meaning |
|---|---|
| 0 | Do Nothing |
| 18 | LAND Mode |
| 46 | RC Override Enable |
| 65 | GPS Disable |
| 81 | Disarm |
| 90 | EKF Source Set |
| 100 | KillIMU1 |
| 101 | KillIMU2 |
| 103 | EKF lane switch attempt |
| 104 | EKF yaw reset |
| 110 | KillIMU3 |
| 111 | Loweheiser starter |
| 112 | SwitchExternalAHRS |
| 153 | ArmDisarm |
| 164 | Pause Stream Logging |
| 166 | Camera Record Video |
| 167 | Camera Zoom |
| 168 | Camera Manual Focus |
| 169 | Camera Auto Focus |
| 171 | Calibrate Compasses |
| 172 | Battery MPPT Enable |
| 174 | Camera Image Tracking |
| 175 | Camera Lens |
| 177 | Mount LRF enable |
| 218 | Loweheiser throttle |
| 300 | Scripting1 |
| 301 | Scripting2 |
| 302 | Scripting3 |
| 303 | Scripting4 |
| 304 | Scripting5 |
| 305 | Scripting6 |
| 306 | Scripting7 |
| 307 | Scripting8 |
| 308 | Scripting9 |
| 309 | Scripting10 |
| 310 | Scripting11 |
| 311 | Scripting12 |
| 312 | Scripting13 |
| 313 | Scripting14 |
| 314 | Scripting15 |
| 315 | Scripting16 |
| 316 | Stop-Restart Scripting |
RC minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
RC trim (neutral) PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
RC maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse channel input. Set to 0 for normal operation. Set to 1 to reverse this input channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
PWM dead zone in microseconds around trim or bottom
Function assigned to this RC channel
| Value | Meaning |
|---|---|
| 0 | Do Nothing |
| 18 | LAND Mode |
| 46 | RC Override Enable |
| 65 | GPS Disable |
| 81 | Disarm |
| 90 | EKF Source Set |
| 100 | KillIMU1 |
| 101 | KillIMU2 |
| 103 | EKF lane switch attempt |
| 104 | EKF yaw reset |
| 110 | KillIMU3 |
| 111 | Loweheiser starter |
| 112 | SwitchExternalAHRS |
| 153 | ArmDisarm |
| 164 | Pause Stream Logging |
| 166 | Camera Record Video |
| 167 | Camera Zoom |
| 168 | Camera Manual Focus |
| 169 | Camera Auto Focus |
| 171 | Calibrate Compasses |
| 172 | Battery MPPT Enable |
| 174 | Camera Image Tracking |
| 175 | Camera Lens |
| 177 | Mount LRF enable |
| 218 | Loweheiser throttle |
| 300 | Scripting1 |
| 301 | Scripting2 |
| 302 | Scripting3 |
| 303 | Scripting4 |
| 304 | Scripting5 |
| 305 | Scripting6 |
| 306 | Scripting7 |
| 307 | Scripting8 |
| 308 | Scripting9 |
| 309 | Scripting10 |
| 310 | Scripting11 |
| 311 | Scripting12 |
| 312 | Scripting13 |
| 313 | Scripting14 |
| 314 | Scripting15 |
| 315 | Scripting16 |
| 316 | Stop-Restart Scripting |
RC minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
RC trim (neutral) PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
RC maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse channel input. Set to 0 for normal operation. Set to 1 to reverse this input channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
PWM dead zone in microseconds around trim or bottom
Function assigned to this RC channel
| Value | Meaning |
|---|---|
| 0 | Do Nothing |
| 18 | LAND Mode |
| 46 | RC Override Enable |
| 65 | GPS Disable |
| 81 | Disarm |
| 90 | EKF Source Set |
| 100 | KillIMU1 |
| 101 | KillIMU2 |
| 103 | EKF lane switch attempt |
| 104 | EKF yaw reset |
| 110 | KillIMU3 |
| 111 | Loweheiser starter |
| 112 | SwitchExternalAHRS |
| 153 | ArmDisarm |
| 164 | Pause Stream Logging |
| 166 | Camera Record Video |
| 167 | Camera Zoom |
| 168 | Camera Manual Focus |
| 169 | Camera Auto Focus |
| 171 | Calibrate Compasses |
| 172 | Battery MPPT Enable |
| 174 | Camera Image Tracking |
| 175 | Camera Lens |
| 177 | Mount LRF enable |
| 218 | Loweheiser throttle |
| 300 | Scripting1 |
| 301 | Scripting2 |
| 302 | Scripting3 |
| 303 | Scripting4 |
| 304 | Scripting5 |
| 305 | Scripting6 |
| 306 | Scripting7 |
| 307 | Scripting8 |
| 308 | Scripting9 |
| 309 | Scripting10 |
| 310 | Scripting11 |
| 311 | Scripting12 |
| 312 | Scripting13 |
| 313 | Scripting14 |
| 314 | Scripting15 |
| 315 | Scripting16 |
| 316 | Stop-Restart Scripting |
RC minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
RC trim (neutral) PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
RC maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse channel input. Set to 0 for normal operation. Set to 1 to reverse this input channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
PWM dead zone in microseconds around trim or bottom
Function assigned to this RC channel
| Value | Meaning |
|---|---|
| 0 | Do Nothing |
| 18 | LAND Mode |
| 46 | RC Override Enable |
| 65 | GPS Disable |
| 81 | Disarm |
| 90 | EKF Source Set |
| 100 | KillIMU1 |
| 101 | KillIMU2 |
| 103 | EKF lane switch attempt |
| 104 | EKF yaw reset |
| 110 | KillIMU3 |
| 111 | Loweheiser starter |
| 112 | SwitchExternalAHRS |
| 153 | ArmDisarm |
| 164 | Pause Stream Logging |
| 166 | Camera Record Video |
| 167 | Camera Zoom |
| 168 | Camera Manual Focus |
| 169 | Camera Auto Focus |
| 171 | Calibrate Compasses |
| 172 | Battery MPPT Enable |
| 174 | Camera Image Tracking |
| 175 | Camera Lens |
| 177 | Mount LRF enable |
| 218 | Loweheiser throttle |
| 300 | Scripting1 |
| 301 | Scripting2 |
| 302 | Scripting3 |
| 303 | Scripting4 |
| 304 | Scripting5 |
| 305 | Scripting6 |
| 306 | Scripting7 |
| 307 | Scripting8 |
| 308 | Scripting9 |
| 309 | Scripting10 |
| 310 | Scripting11 |
| 311 | Scripting12 |
| 312 | Scripting13 |
| 313 | Scripting14 |
| 314 | Scripting15 |
| 315 | Scripting16 |
| 316 | Stop-Restart Scripting |
RC minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
RC trim (neutral) PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
RC maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse channel input. Set to 0 for normal operation. Set to 1 to reverse this input channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
PWM dead zone in microseconds around trim or bottom
Function assigned to this RC channel
| Value | Meaning |
|---|---|
| 0 | Do Nothing |
| 18 | LAND Mode |
| 46 | RC Override Enable |
| 65 | GPS Disable |
| 81 | Disarm |
| 90 | EKF Source Set |
| 100 | KillIMU1 |
| 101 | KillIMU2 |
| 103 | EKF lane switch attempt |
| 104 | EKF yaw reset |
| 110 | KillIMU3 |
| 111 | Loweheiser starter |
| 112 | SwitchExternalAHRS |
| 153 | ArmDisarm |
| 164 | Pause Stream Logging |
| 166 | Camera Record Video |
| 167 | Camera Zoom |
| 168 | Camera Manual Focus |
| 169 | Camera Auto Focus |
| 171 | Calibrate Compasses |
| 172 | Battery MPPT Enable |
| 174 | Camera Image Tracking |
| 175 | Camera Lens |
| 177 | Mount LRF enable |
| 218 | Loweheiser throttle |
| 300 | Scripting1 |
| 301 | Scripting2 |
| 302 | Scripting3 |
| 303 | Scripting4 |
| 304 | Scripting5 |
| 305 | Scripting6 |
| 306 | Scripting7 |
| 307 | Scripting8 |
| 308 | Scripting9 |
| 309 | Scripting10 |
| 310 | Scripting11 |
| 311 | Scripting12 |
| 312 | Scripting13 |
| 313 | Scripting14 |
| 314 | Scripting15 |
| 315 | Scripting16 |
| 316 | Stop-Restart Scripting |
Roll channel number. This is useful when you have a RC transmitter that can't change the channel order easily. Roll is normally on channel 1, but you can move it to any channel with this parameter. Reboot is required for changes to take effect.
Pitch channel number. This is useful when you have a RC transmitter that can't change the channel order easily. Pitch is normally on channel 2, but you can move it to any channel with this parameter. Reboot is required for changes to take effect.
Throttle channel number. This is useful when you have a RC transmitter that can't change the channel order easily. Throttle is normally on channel 3, but you can move it to any channel with this parameter. Reboot is required for changes to take effect.
Yaw channel number. This is useful when you have a RC transmitter that can't change the channel order easily. Yaw (also known as rudder) is normally on channel 4, but you can move it to any channel with this parameter. Reboot is required for changes to take effect.
What type of RPM sensor is connected
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Not Used |
| 2 | GPIO |
| 3 | EFI |
| 4 | Harmonic Notch |
| 5 | ESC Telemetry Motors Bitmask |
| 6 | Generator |
| 7 | DroneCAN |
Scaling factor between sensor reading and RPM.
Maximum RPM to report. Only used on type = GPIO.
Minimum RPM to report. Only used on type = GPIO.
Minimum data quality to be used
Which digital GPIO pin to use. Only used on type = GPIO. Some common values are given, but see the Wiki's "GPIOs" page for how to determine the pin number for a given autopilot.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 50 | AUX1 |
| 51 | AUX2 |
| 52 | AUX3 |
| 53 | AUX4 |
| 54 | AUX5 |
| 55 | AUX6 |
Mask of channels which support ESC rpm telemetry. RPM telemetry of the selected channels will be averaged
ESC Telemetry Index to write RPM to. Use 0 to disable.
DroneCAN sensor ID to assign to this backend
What type of RPM sensor is connected
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Not Used |
| 2 | GPIO |
| 3 | EFI |
| 4 | Harmonic Notch |
| 5 | ESC Telemetry Motors Bitmask |
| 6 | Generator |
| 7 | DroneCAN |
Scaling factor between sensor reading and RPM.
Maximum RPM to report. Only used on type = GPIO.
Minimum RPM to report. Only used on type = GPIO.
Minimum data quality to be used
Which digital GPIO pin to use. Only used on type = GPIO. Some common values are given, but see the Wiki's "GPIOs" page for how to determine the pin number for a given autopilot.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 50 | AUX1 |
| 51 | AUX2 |
| 52 | AUX3 |
| 53 | AUX4 |
| 54 | AUX5 |
| 55 | AUX6 |
Mask of channels which support ESC rpm telemetry. RPM telemetry of the selected channels will be averaged
ESC Telemetry Index to write RPM to. Use 0 to disable.
DroneCAN sensor ID to assign to this backend
What type of RPM sensor is connected
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Not Used |
| 2 | GPIO |
| 3 | EFI |
| 4 | Harmonic Notch |
| 5 | ESC Telemetry Motors Bitmask |
| 6 | Generator |
| 7 | DroneCAN |
Scaling factor between sensor reading and RPM.
Maximum RPM to report. Only used on type = GPIO.
Minimum RPM to report. Only used on type = GPIO.
Minimum data quality to be used
Which digital GPIO pin to use. Only used on type = GPIO. Some common values are given, but see the Wiki's "GPIOs" page for how to determine the pin number for a given autopilot.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 50 | AUX1 |
| 51 | AUX2 |
| 52 | AUX3 |
| 53 | AUX4 |
| 54 | AUX5 |
| 55 | AUX6 |
Mask of channels which support ESC rpm telemetry. RPM telemetry of the selected channels will be averaged
ESC Telemetry Index to write RPM to. Use 0 to disable.
DroneCAN sensor ID to assign to this backend
What type of RPM sensor is connected
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Not Used |
| 2 | GPIO |
| 3 | EFI |
| 4 | Harmonic Notch |
| 5 | ESC Telemetry Motors Bitmask |
| 6 | Generator |
| 7 | DroneCAN |
Scaling factor between sensor reading and RPM.
Maximum RPM to report. Only used on type = GPIO.
Minimum RPM to report. Only used on type = GPIO.
Minimum data quality to be used
Which digital GPIO pin to use. Only used on type = GPIO. Some common values are given, but see the Wiki's "GPIOs" page for how to determine the pin number for a given autopilot.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 50 | AUX1 |
| 51 | AUX2 |
| 52 | AUX3 |
| 53 | AUX4 |
| 54 | AUX5 |
| 55 | AUX6 |
Mask of channels which support ESC rpm telemetry. RPM telemetry of the selected channels will be averaged
ESC Telemetry Index to write RPM to. Use 0 to disable.
DroneCAN sensor ID to assign to this backend
Radio Receiver RSSI type. If your radio receiver supports RSSI of some kind, set it here, then set its associated RSSI_XXXXX parameters, if any.
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | AnalogPin |
| 2 | RCChannelPwmValue |
| 3 | ReceiverProtocol |
| 4 | PWMInputPin |
| 5 | TelemetryRadioRSSI |
Pin used to read the RSSI voltage or PWM value. Analog Airspeed ports can be used for Analog inputs (some autopilots provide others also), Non-IOMCU Servo/MotorOutputs can be used for PWM input when configured as "GPIOs". Values for some autopilots are given as examples. Search wiki for "Analog pins" for analog pin or "GPIOs", if PWM input type, to determine pin number.
| Value | Meaning |
|---|---|
| 8 | V5 Nano |
| 11 | Pixracer |
| 13 | Pixhawk ADC4 |
| 14 | Pixhawk ADC3 |
| 15 | Pixhawk ADC6/Pixhawk2 ADC |
| 50 | AUX1 |
| 51 | AUX2 |
| 52 | AUX3 |
| 53 | AUX4 |
| 54 | AUX5 |
| 55 | AUX6 |
| 103 | Pixhawk SBUS |
RSSI pin's voltage received on the RSSI_ANA_PIN when the signal strength is the weakest. Some radio receivers put out inverted values so this value may be higher than RSSI_PIN_HIGH. When using pin 103, the maximum value of the parameter is 3.3V.
RSSI pin's voltage received on the RSSI_ANA_PIN when the signal strength is the strongest. Some radio receivers put out inverted values so this value may be lower than RSSI_PIN_LOW. When using pin 103, the maximum value of the parameter is 3.3V.
The channel number where RSSI will be output by the radio receiver (5 and above).
PWM value that the radio receiver will put on the RSSI_CHANNEL or RSSI_ANA_PIN when the signal strength is the weakest. Some radio receivers output inverted values so this value may be lower than RSSI_CHAN_HIGH
PWM value that the radio receiver will put on the RSSI_CHANNEL or RSSI_ANA_PIN when the signal strength is the strongest. Some radio receivers output inverted values so this value may be higher than RSSI_CHAN_LOW
Set to non-zero to enable scheduler debug messages. When set to show "Slips" the scheduler will display a message whenever a scheduled task is delayed due to too much CPU load. When set to ShowOverruns the scheduled will display a message whenever a task takes longer than the limit promised in the task table.
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 2 | ShowSlips |
| 3 | ShowOverruns |
This controls the rate of the main control loop in Hz. This should only be changed by developers. This only takes effect on restart. Values over 400 are considered highly experimental.
This controls optional aspects of the scheduler.
Controls if scripting is enabled
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | Lua Scripts |
The number virtual machine instructions that can be run before considering a script to have taken an excessive amount of time
Amount of memory available for scripting
Debugging options
General purpose user variable input for scripts
General purpose user variable input for scripts
General purpose user variable input for scripts
General purpose user variable input for scripts
General purpose user variable input for scripts
General purpose user variable input for scripts
This will stop scripts being loaded from the given locations
Required XOR of CRC32 checksum of loaded scripts, vehicle will not arm with incorrect scripts loaded, -1 disables
Required XOR of CRC32 checksum of running scripts, vehicle will not arm with incorrect scripts running, -1 disables
This sets the priority of the scripting thread. This is normally set to a low priority to prevent scripts from interfering with other parts of the system. Advanced users can change this priority if scripting needs to be prioritised for realtime applications. WARNING: changing this parameter can impact the stability of your flight controller. The scipting thread priority in this parameter is chosen based on a set of system level priorities for other subsystems. It is strongly recommended that you use the lowest priority that is sufficient for your application. Note that all scripts run at the same priority, so if you raise this priority you must carefully audit all lua scripts for behaviour that does not interfere with the operation of the system.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | IO Priority |
| 2 | Storage Priority |
| 3 | UART Priority |
| 4 | I2C Priority |
| 5 | SPI Priority |
| 6 | Timer Priority |
| 7 | Main Priority |
| 8 | Boost Priority |
Enable scripting serial devices
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
Serial protocol of scripting serial device
| Value | Meaning |
|---|---|
| -1 | None |
| 1 | MAVLink1 |
| 2 | MAVLink2 |
| 3 | Frsky D |
| 4 | Frsky SPort |
| 5 | GPS |
| 7 | Alexmos Gimbal Serial |
| 8 | Gimbal |
| 9 | Rangefinder |
| 10 | FrSky SPort Passthrough (OpenTX) |
| 11 | Lidar360 |
| 13 | Beacon |
| 14 | Volz servo out |
| 15 | SBus servo out |
| 16 | ESC Telemetry |
| 17 | Devo Telemetry |
| 18 | OpticalFlow |
| 19 | RobotisServo |
| 20 | NMEA Output |
| 21 | WindVane |
| 22 | SLCAN |
| 23 | RCIN |
| 24 | EFI Serial |
| 25 | LTM |
| 26 | RunCam |
| 27 | HottTelem |
| 28 | Scripting |
| 29 | Crossfire VTX |
| 30 | Generator |
| 31 | Winch |
| 32 | MSP |
| 33 | DJI FPV |
| 34 | AirSpeed |
| 35 | ADSB |
| 36 | AHRS |
| 37 | SmartAudio |
| 38 | FETtecOneWire |
| 39 | Torqeedo |
| 40 | AIS |
| 41 | CoDevESC |
| 42 | DisplayPort |
| 43 | MAVLink High Latency |
| 44 | IRC Tramp |
| 45 | DDS XRCE |
| 46 | IMUDATA |
| 48 | PPP |
| 49 | i-BUS Telemetry |
| 50 | IOMCU |
Serial protocol of scripting serial device
| Value | Meaning |
|---|---|
| -1 | None |
| 1 | MAVLink1 |
| 2 | MAVLink2 |
| 3 | Frsky D |
| 4 | Frsky SPort |
| 5 | GPS |
| 7 | Alexmos Gimbal Serial |
| 8 | Gimbal |
| 9 | Rangefinder |
| 10 | FrSky SPort Passthrough (OpenTX) |
| 11 | Lidar360 |
| 13 | Beacon |
| 14 | Volz servo out |
| 15 | SBus servo out |
| 16 | ESC Telemetry |
| 17 | Devo Telemetry |
| 18 | OpticalFlow |
| 19 | RobotisServo |
| 20 | NMEA Output |
| 21 | WindVane |
| 22 | SLCAN |
| 23 | RCIN |
| 24 | EFI Serial |
| 25 | LTM |
| 26 | RunCam |
| 27 | HottTelem |
| 28 | Scripting |
| 29 | Crossfire VTX |
| 30 | Generator |
| 31 | Winch |
| 32 | MSP |
| 33 | DJI FPV |
| 34 | AirSpeed |
| 35 | ADSB |
| 36 | AHRS |
| 37 | SmartAudio |
| 38 | FETtecOneWire |
| 39 | Torqeedo |
| 40 | AIS |
| 41 | CoDevESC |
| 42 | DisplayPort |
| 43 | MAVLink High Latency |
| 44 | IRC Tramp |
| 45 | DDS XRCE |
| 46 | IMUDATA |
| 48 | PPP |
| 49 | i-BUS Telemetry |
| 50 | IOMCU |
Serial protocol of scripting serial device
| Value | Meaning |
|---|---|
| -1 | None |
| 1 | MAVLink1 |
| 2 | MAVLink2 |
| 3 | Frsky D |
| 4 | Frsky SPort |
| 5 | GPS |
| 7 | Alexmos Gimbal Serial |
| 8 | Gimbal |
| 9 | Rangefinder |
| 10 | FrSky SPort Passthrough (OpenTX) |
| 11 | Lidar360 |
| 13 | Beacon |
| 14 | Volz servo out |
| 15 | SBus servo out |
| 16 | ESC Telemetry |
| 17 | Devo Telemetry |
| 18 | OpticalFlow |
| 19 | RobotisServo |
| 20 | NMEA Output |
| 21 | WindVane |
| 22 | SLCAN |
| 23 | RCIN |
| 24 | EFI Serial |
| 25 | LTM |
| 26 | RunCam |
| 27 | HottTelem |
| 28 | Scripting |
| 29 | Crossfire VTX |
| 30 | Generator |
| 31 | Winch |
| 32 | MSP |
| 33 | DJI FPV |
| 34 | AirSpeed |
| 35 | ADSB |
| 36 | AHRS |
| 37 | SmartAudio |
| 38 | FETtecOneWire |
| 39 | Torqeedo |
| 40 | AIS |
| 41 | CoDevESC |
| 42 | DisplayPort |
| 43 | MAVLink High Latency |
| 44 | IRC Tramp |
| 45 | DDS XRCE |
| 46 | IMUDATA |
| 48 | PPP |
| 49 | i-BUS Telemetry |
| 50 | IOMCU |
The baud rate used on the USB console. Most stm32-based boards can support rates of up to 1500. If you setup a rate you cannot support and then can't connect to your board you should load a firmware from a different vehicle type. That will reset all your parameters to defaults.
| Value | Meaning |
|---|---|
| 1 | 1200 |
| 2 | 2400 |
| 4 | 4800 |
| 9 | 9600 |
| 19 | 19200 |
| 38 | 38400 |
| 57 | 57600 |
| 111 | 111100 |
| 115 | 115200 |
| 230 | 230400 |
| 256 | 256000 |
| 460 | 460800 |
| 500 | 500000 |
| 921 | 921600 |
| 1500 | 1.5MBaud |
| 2000 | 2MBaud |
| 12500000 | 12.5MBaud |
Control what protocol to use on the console.
| Value | Meaning |
|---|---|
| 1 | MAVLink1 |
| 2 | MAVLink2 |
Control what protocol to use on the Telem1 port. Note that the Frsky options require external converter hardware. See the wiki for details.
| Value | Meaning |
|---|---|
| -1 | None |
| 1 | MAVLink1 |
| 2 | MAVLink2 |
| 3 | Frsky D |
| 4 | Frsky SPort |
| 5 | GPS |
| 7 | Alexmos Gimbal Serial |
| 8 | Gimbal |
| 9 | Rangefinder |
| 10 | FrSky SPort Passthrough (OpenTX) |
| 11 | Lidar360 |
| 13 | Beacon |
| 14 | Volz servo out |
| 15 | SBus servo out |
| 16 | ESC Telemetry |
| 17 | Devo Telemetry |
| 18 | OpticalFlow |
| 19 | RobotisServo |
| 20 | NMEA Output |
| 21 | WindVane |
| 22 | SLCAN |
| 23 | RCIN |
| 24 | EFI Serial |
| 25 | LTM |
| 26 | RunCam |
| 27 | HottTelem |
| 28 | Scripting |
| 29 | Crossfire VTX |
| 30 | Generator |
| 31 | Winch |
| 32 | MSP |
| 33 | DJI FPV |
| 34 | AirSpeed |
| 35 | ADSB |
| 36 | AHRS |
| 37 | SmartAudio |
| 38 | FETtecOneWire |
| 39 | Torqeedo |
| 40 | AIS |
| 41 | CoDevESC |
| 42 | DisplayPort |
| 43 | MAVLink High Latency |
| 44 | IRC Tramp |
| 45 | DDS XRCE |
| 46 | IMUDATA |
| 48 | PPP |
| 49 | i-BUS Telemetry |
| 50 | IOMCU |
The baud rate used on the Telem1 port. Most stm32-based boards can support rates of up to 1500. If you setup a rate you cannot support and then can't connect to your board you should load a firmware from a different vehicle type. That will reset all your parameters to defaults.
| Value | Meaning |
|---|---|
| 1 | 1200 |
| 2 | 2400 |
| 4 | 4800 |
| 9 | 9600 |
| 19 | 19200 |
| 38 | 38400 |
| 57 | 57600 |
| 111 | 111100 |
| 115 | 115200 |
| 230 | 230400 |
| 256 | 256000 |
| 460 | 460800 |
| 500 | 500000 |
| 921 | 921600 |
| 1500 | 1.5MBaud |
| 2000 | 2MBaud |
| 12500000 | 12.5MBaud |
Control what protocol to use on the Telem2 port. Note that the Frsky options require external converter hardware. See the wiki for details.
| Value | Meaning |
|---|---|
| -1 | None |
| 1 | MAVLink1 |
| 2 | MAVLink2 |
| 3 | Frsky D |
| 4 | Frsky SPort |
| 5 | GPS |
| 7 | Alexmos Gimbal Serial |
| 8 | Gimbal |
| 9 | Rangefinder |
| 10 | FrSky SPort Passthrough (OpenTX) |
| 11 | Lidar360 |
| 13 | Beacon |
| 14 | Volz servo out |
| 15 | SBus servo out |
| 16 | ESC Telemetry |
| 17 | Devo Telemetry |
| 18 | OpticalFlow |
| 19 | RobotisServo |
| 20 | NMEA Output |
| 21 | WindVane |
| 22 | SLCAN |
| 23 | RCIN |
| 24 | EFI Serial |
| 25 | LTM |
| 26 | RunCam |
| 27 | HottTelem |
| 28 | Scripting |
| 29 | Crossfire VTX |
| 30 | Generator |
| 31 | Winch |
| 32 | MSP |
| 33 | DJI FPV |
| 34 | AirSpeed |
| 35 | ADSB |
| 36 | AHRS |
| 37 | SmartAudio |
| 38 | FETtecOneWire |
| 39 | Torqeedo |
| 40 | AIS |
| 41 | CoDevESC |
| 42 | DisplayPort |
| 43 | MAVLink High Latency |
| 44 | IRC Tramp |
| 45 | DDS XRCE |
| 46 | IMUDATA |
| 48 | PPP |
| 49 | i-BUS Telemetry |
| 50 | IOMCU |
The baud rate of the Telem2 port. Most stm32-based boards can support rates of up to 1500. If you setup a rate you cannot support and then can't connect to your board you should load a firmware from a different vehicle type. That will reset all your parameters to defaults.
| Value | Meaning |
|---|---|
| 1 | 1200 |
| 2 | 2400 |
| 4 | 4800 |
| 9 | 9600 |
| 19 | 19200 |
| 38 | 38400 |
| 57 | 57600 |
| 111 | 111100 |
| 115 | 115200 |
| 230 | 230400 |
| 256 | 256000 |
| 460 | 460800 |
| 500 | 500000 |
| 921 | 921600 |
| 1500 | 1.5MBaud |
| 2000 | 2MBaud |
| 12500000 | 12.5MBaud |
Control what protocol Serial 3 (GPS) should be used for. Note that the Frsky options require external converter hardware. See the wiki for details.
| Value | Meaning |
|---|---|
| -1 | None |
| 1 | MAVLink1 |
| 2 | MAVLink2 |
| 3 | Frsky D |
| 4 | Frsky SPort |
| 5 | GPS |
| 7 | Alexmos Gimbal Serial |
| 8 | Gimbal |
| 9 | Rangefinder |
| 10 | FrSky SPort Passthrough (OpenTX) |
| 11 | Lidar360 |
| 13 | Beacon |
| 14 | Volz servo out |
| 15 | SBus servo out |
| 16 | ESC Telemetry |
| 17 | Devo Telemetry |
| 18 | OpticalFlow |
| 19 | RobotisServo |
| 20 | NMEA Output |
| 21 | WindVane |
| 22 | SLCAN |
| 23 | RCIN |
| 24 | EFI Serial |
| 25 | LTM |
| 26 | RunCam |
| 27 | HottTelem |
| 28 | Scripting |
| 29 | Crossfire VTX |
| 30 | Generator |
| 31 | Winch |
| 32 | MSP |
| 33 | DJI FPV |
| 34 | AirSpeed |
| 35 | ADSB |
| 36 | AHRS |
| 37 | SmartAudio |
| 38 | FETtecOneWire |
| 39 | Torqeedo |
| 40 | AIS |
| 41 | CoDevESC |
| 42 | DisplayPort |
| 43 | MAVLink High Latency |
| 44 | IRC Tramp |
| 45 | DDS XRCE |
| 46 | IMUDATA |
| 48 | PPP |
| 49 | i-BUS Telemetry |
| 50 | IOMCU |
The baud rate used for the Serial 3 (GPS). Most stm32-based boards can support rates of up to 1500. If you setup a rate you cannot support and then can't connect to your board you should load a firmware from a different vehicle type. That will reset all your parameters to defaults.
| Value | Meaning |
|---|---|
| 1 | 1200 |
| 2 | 2400 |
| 4 | 4800 |
| 9 | 9600 |
| 19 | 19200 |
| 38 | 38400 |
| 57 | 57600 |
| 111 | 111100 |
| 115 | 115200 |
| 230 | 230400 |
| 256 | 256000 |
| 460 | 460800 |
| 500 | 500000 |
| 921 | 921600 |
| 1500 | 1.5MBaud |
| 2000 | 2MBaud |
| 12500000 | 12.5MBaud |
Control what protocol Serial4 port should be used for. Note that the Frsky options require external converter hardware. See the wiki for details.
| Value | Meaning |
|---|---|
| -1 | None |
| 1 | MAVLink1 |
| 2 | MAVLink2 |
| 3 | Frsky D |
| 4 | Frsky SPort |
| 5 | GPS |
| 7 | Alexmos Gimbal Serial |
| 8 | Gimbal |
| 9 | Rangefinder |
| 10 | FrSky SPort Passthrough (OpenTX) |
| 11 | Lidar360 |
| 13 | Beacon |
| 14 | Volz servo out |
| 15 | SBus servo out |
| 16 | ESC Telemetry |
| 17 | Devo Telemetry |
| 18 | OpticalFlow |
| 19 | RobotisServo |
| 20 | NMEA Output |
| 21 | WindVane |
| 22 | SLCAN |
| 23 | RCIN |
| 24 | EFI Serial |
| 25 | LTM |
| 26 | RunCam |
| 27 | HottTelem |
| 28 | Scripting |
| 29 | Crossfire VTX |
| 30 | Generator |
| 31 | Winch |
| 32 | MSP |
| 33 | DJI FPV |
| 34 | AirSpeed |
| 35 | ADSB |
| 36 | AHRS |
| 37 | SmartAudio |
| 38 | FETtecOneWire |
| 39 | Torqeedo |
| 40 | AIS |
| 41 | CoDevESC |
| 42 | DisplayPort |
| 43 | MAVLink High Latency |
| 44 | IRC Tramp |
| 45 | DDS XRCE |
| 46 | IMUDATA |
| 48 | PPP |
| 49 | i-BUS Telemetry |
| 50 | IOMCU |
The baud rate used for Serial4. Most stm32-based boards can support rates of up to 1500. If you setup a rate you cannot support and then can't connect to your board you should load a firmware from a different vehicle type. That will reset all your parameters to defaults.
| Value | Meaning |
|---|---|
| 1 | 1200 |
| 2 | 2400 |
| 4 | 4800 |
| 9 | 9600 |
| 19 | 19200 |
| 38 | 38400 |
| 57 | 57600 |
| 111 | 111100 |
| 115 | 115200 |
| 230 | 230400 |
| 256 | 256000 |
| 460 | 460800 |
| 500 | 500000 |
| 921 | 921600 |
| 1500 | 1.5MBaud |
| 2000 | 2MBaud |
| 12500000 | 12.5MBaud |
Control what protocol Serial5 port should be used for. Note that the Frsky options require external converter hardware. See the wiki for details.
| Value | Meaning |
|---|---|
| -1 | None |
| 1 | MAVLink1 |
| 2 | MAVLink2 |
| 3 | Frsky D |
| 4 | Frsky SPort |
| 5 | GPS |
| 7 | Alexmos Gimbal Serial |
| 8 | Gimbal |
| 9 | Rangefinder |
| 10 | FrSky SPort Passthrough (OpenTX) |
| 11 | Lidar360 |
| 13 | Beacon |
| 14 | Volz servo out |
| 15 | SBus servo out |
| 16 | ESC Telemetry |
| 17 | Devo Telemetry |
| 18 | OpticalFlow |
| 19 | RobotisServo |
| 20 | NMEA Output |
| 21 | WindVane |
| 22 | SLCAN |
| 23 | RCIN |
| 24 | EFI Serial |
| 25 | LTM |
| 26 | RunCam |
| 27 | HottTelem |
| 28 | Scripting |
| 29 | Crossfire VTX |
| 30 | Generator |
| 31 | Winch |
| 32 | MSP |
| 33 | DJI FPV |
| 34 | AirSpeed |
| 35 | ADSB |
| 36 | AHRS |
| 37 | SmartAudio |
| 38 | FETtecOneWire |
| 39 | Torqeedo |
| 40 | AIS |
| 41 | CoDevESC |
| 42 | DisplayPort |
| 43 | MAVLink High Latency |
| 44 | IRC Tramp |
| 45 | DDS XRCE |
| 46 | IMUDATA |
| 48 | PPP |
| 49 | i-BUS Telemetry |
| 50 | IOMCU |
The baud rate used for Serial5. Most stm32-based boards can support rates of up to 1500. If you setup a rate you cannot support and then can't connect to your board you should load a firmware from a different vehicle type. That will reset all your parameters to defaults.
| Value | Meaning |
|---|---|
| 1 | 1200 |
| 2 | 2400 |
| 4 | 4800 |
| 9 | 9600 |
| 19 | 19200 |
| 38 | 38400 |
| 57 | 57600 |
| 111 | 111100 |
| 115 | 115200 |
| 230 | 230400 |
| 256 | 256000 |
| 460 | 460800 |
| 500 | 500000 |
| 921 | 921600 |
| 1500 | 1.5MBaud |
| 2000 | 2MBaud |
| 12500000 | 12.5MBaud |
Control what protocol Serial6 port should be used for. Note that the Frsky options require external converter hardware. See the wiki for details.
| Value | Meaning |
|---|---|
| -1 | None |
| 1 | MAVLink1 |
| 2 | MAVLink2 |
| 3 | Frsky D |
| 4 | Frsky SPort |
| 5 | GPS |
| 7 | Alexmos Gimbal Serial |
| 8 | Gimbal |
| 9 | Rangefinder |
| 10 | FrSky SPort Passthrough (OpenTX) |
| 11 | Lidar360 |
| 13 | Beacon |
| 14 | Volz servo out |
| 15 | SBus servo out |
| 16 | ESC Telemetry |
| 17 | Devo Telemetry |
| 18 | OpticalFlow |
| 19 | RobotisServo |
| 20 | NMEA Output |
| 21 | WindVane |
| 22 | SLCAN |
| 23 | RCIN |
| 24 | EFI Serial |
| 25 | LTM |
| 26 | RunCam |
| 27 | HottTelem |
| 28 | Scripting |
| 29 | Crossfire VTX |
| 30 | Generator |
| 31 | Winch |
| 32 | MSP |
| 33 | DJI FPV |
| 34 | AirSpeed |
| 35 | ADSB |
| 36 | AHRS |
| 37 | SmartAudio |
| 38 | FETtecOneWire |
| 39 | Torqeedo |
| 40 | AIS |
| 41 | CoDevESC |
| 42 | DisplayPort |
| 43 | MAVLink High Latency |
| 44 | IRC Tramp |
| 45 | DDS XRCE |
| 46 | IMUDATA |
| 48 | PPP |
| 49 | i-BUS Telemetry |
| 50 | IOMCU |
The baud rate used for Serial6. Most stm32-based boards can support rates of up to 1500. If you setup a rate you cannot support and then can't connect to your board you should load a firmware from a different vehicle type. That will reset all your parameters to defaults.
| Value | Meaning |
|---|---|
| 1 | 1200 |
| 2 | 2400 |
| 4 | 4800 |
| 9 | 9600 |
| 19 | 19200 |
| 38 | 38400 |
| 57 | 57600 |
| 111 | 111100 |
| 115 | 115200 |
| 230 | 230400 |
| 256 | 256000 |
| 460 | 460800 |
| 500 | 500000 |
| 921 | 921600 |
| 1500 | 1.5MBaud |
| 2000 | 2MBaud |
| 12500000 | 12.5MBaud |
Control over UART options. The InvertRX option controls invert of the receive pin. The InvertTX option controls invert of the transmit pin. The HalfDuplex option controls half-duplex (onewire) mode, where both transmit and receive is done on the transmit wire. The Swap option allows the RX and TX pins to be swapped on STM32F7 based boards. NOTE that two bits have moved from this parameter into MAVn_OPTIONS!
Control over UART options. The InvertRX option controls invert of the receive pin. The InvertTX option controls invert of the transmit pin. The HalfDuplex option controls half-duplex (onewire) mode, where both transmit and receive is done on the transmit wire. The Swap option allows the RX and TX pins to be swapped on STM32F7 based boards. NOTE that two bits have moved from this parameter into MAVn_OPTIONS!
Control over UART options. The InvertRX option controls invert of the receive pin. The InvertTX option controls invert of the transmit pin. The HalfDuplex option controls half-duplex (onewire) mode, where both transmit and receive is done on the transmit wire. The Swap option allows the RX and TX pins to be swapped on STM32F7 based boards. NOTE that two bits have moved from this parameter into MAVn_OPTIONS!
Control over UART options. The InvertRX option controls invert of the receive pin. The InvertTX option controls invert of the transmit pin. The HalfDuplex option controls half-duplex (onewire) mode, where both transmit and receive is done on the transmit wire. The Swap option allows the RX and TX pins to be swapped on STM32F7 based boards. NOTE that two bits have moved from this parameter into MAVn_OPTIONS!
Control over UART options. The InvertRX option controls invert of the receive pin. The InvertTX option controls invert of the transmit pin. The HalfDuplex option controls half-duplex (onewire) mode, where both transmit and receive is done on the transmit wire. The Swap option allows the RX and TX pins to be swapped on STM32F7 based boards. NOTE that two bits have moved from this parameter into MAVn_OPTIONS!
Control over UART options. The InvertRX option controls invert of the receive pin. The InvertTX option controls invert of the transmit pin. The HalfDuplex option controls half-duplex (onewire) mode, where both transmit and receive is done on the transmit wire. The Swap option allows the RX and TX pins to be swapped on STM32F7 based boards. NOTE that two bits have moved from this parameter into MAVn_OPTIONS!
This sets one side of pass-through between two serial ports. Once both sides are set then all data received on either port will be passed to the other port
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 0 | Serial0 |
| 1 | Serial1 |
| 2 | Serial2 |
| 3 | Serial3 |
| 4 | Serial4 |
| 5 | Serial5 |
| 6 | Serial6 |
This sets one side of pass-through between two serial ports. Once both sides are set then all data received on either port will be passed to the other port. This parameter is normally reset to -1 on reboot, disabling passthrough. If SERIAL_PASSTIMO is set to -1 then it is not reset on reboot.
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 0 | Serial0 |
| 1 | Serial1 |
| 2 | Serial2 |
| 3 | Serial3 |
| 4 | Serial4 |
| 5 | Serial5 |
| 6 | Serial6 |
This sets a timeout for serial pass-through in seconds. When the pass-through is enabled by setting the SERIAL_PASS1 and SERIAL_PASS2 parameters then it remains in effect until no data comes from the first port for SERIAL_PASSTIMO seconds. This allows the port to revent to its normal usage (such as MAVLink connection to a GCS) when it is no longer needed. A value of 0 means no timeout. A value of -1 means no timeout and the SERIAL_PASS2 parameter is not reset on reboot.
Control what protocol Serial7 port should be used for. Note that the Frsky options require external converter hardware. See the wiki for details.
| Value | Meaning |
|---|---|
| -1 | None |
| 1 | MAVLink1 |
| 2 | MAVLink2 |
| 3 | Frsky D |
| 4 | Frsky SPort |
| 5 | GPS |
| 7 | Alexmos Gimbal Serial |
| 8 | Gimbal |
| 9 | Rangefinder |
| 10 | FrSky SPort Passthrough (OpenTX) |
| 11 | Lidar360 |
| 13 | Beacon |
| 14 | Volz servo out |
| 15 | SBus servo out |
| 16 | ESC Telemetry |
| 17 | Devo Telemetry |
| 18 | OpticalFlow |
| 19 | RobotisServo |
| 20 | NMEA Output |
| 21 | WindVane |
| 22 | SLCAN |
| 23 | RCIN |
| 24 | EFI Serial |
| 25 | LTM |
| 26 | RunCam |
| 27 | HottTelem |
| 28 | Scripting |
| 29 | Crossfire VTX |
| 30 | Generator |
| 31 | Winch |
| 32 | MSP |
| 33 | DJI FPV |
| 34 | AirSpeed |
| 35 | ADSB |
| 36 | AHRS |
| 37 | SmartAudio |
| 38 | FETtecOneWire |
| 39 | Torqeedo |
| 40 | AIS |
| 41 | CoDevESC |
| 42 | DisplayPort |
| 43 | MAVLink High Latency |
| 44 | IRC Tramp |
| 45 | DDS XRCE |
| 46 | IMUDATA |
| 48 | PPP |
| 49 | i-BUS Telemetry |
| 50 | IOMCU |
The baud rate used for Serial7. Most stm32-based boards can support rates of up to 1500. If you setup a rate you cannot support and then can't connect to your board you should load a firmware from a different vehicle type. That will reset all your parameters to defaults.
| Value | Meaning |
|---|---|
| 1 | 1200 |
| 2 | 2400 |
| 4 | 4800 |
| 9 | 9600 |
| 19 | 19200 |
| 38 | 38400 |
| 57 | 57600 |
| 111 | 111100 |
| 115 | 115200 |
| 230 | 230400 |
| 256 | 256000 |
| 460 | 460800 |
| 500 | 500000 |
| 921 | 921600 |
| 1500 | 1.5MBaud |
| 2000 | 2MBaud |
| 12500000 | 12.5MBaud |
Control over UART options. The InvertRX option controls invert of the receive pin. The InvertTX option controls invert of the transmit pin. The HalfDuplex option controls half-duplex (onewire) mode, where both transmit and receive is done on the transmit wire. The Swap option allows the RX and TX pins to be swapped on STM32F7 based boards. NOTE that two bits have moved from this parameter into MAVn_OPTIONS!
Control what protocol Serial8 port should be used for. Note that the Frsky options require external converter hardware. See the wiki for details.
| Value | Meaning |
|---|---|
| -1 | None |
| 1 | MAVLink1 |
| 2 | MAVLink2 |
| 3 | Frsky D |
| 4 | Frsky SPort |
| 5 | GPS |
| 7 | Alexmos Gimbal Serial |
| 8 | Gimbal |
| 9 | Rangefinder |
| 10 | FrSky SPort Passthrough (OpenTX) |
| 11 | Lidar360 |
| 13 | Beacon |
| 14 | Volz servo out |
| 15 | SBus servo out |
| 16 | ESC Telemetry |
| 17 | Devo Telemetry |
| 18 | OpticalFlow |
| 19 | RobotisServo |
| 20 | NMEA Output |
| 21 | WindVane |
| 22 | SLCAN |
| 23 | RCIN |
| 24 | EFI Serial |
| 25 | LTM |
| 26 | RunCam |
| 27 | HottTelem |
| 28 | Scripting |
| 29 | Crossfire VTX |
| 30 | Generator |
| 31 | Winch |
| 32 | MSP |
| 33 | DJI FPV |
| 34 | AirSpeed |
| 35 | ADSB |
| 36 | AHRS |
| 37 | SmartAudio |
| 38 | FETtecOneWire |
| 39 | Torqeedo |
| 40 | AIS |
| 41 | CoDevESC |
| 42 | DisplayPort |
| 43 | MAVLink High Latency |
| 44 | IRC Tramp |
| 45 | DDS XRCE |
| 46 | IMUDATA |
| 48 | PPP |
| 49 | i-BUS Telemetry |
| 50 | IOMCU |
The baud rate used for Serial8. Most stm32-based boards can support rates of up to 1500. If you setup a rate you cannot support and then can't connect to your board you should load a firmware from a different vehicle type. That will reset all your parameters to defaults.
| Value | Meaning |
|---|---|
| 1 | 1200 |
| 2 | 2400 |
| 4 | 4800 |
| 9 | 9600 |
| 19 | 19200 |
| 38 | 38400 |
| 57 | 57600 |
| 111 | 111100 |
| 115 | 115200 |
| 230 | 230400 |
| 256 | 256000 |
| 460 | 460800 |
| 500 | 500000 |
| 921 | 921600 |
| 1500 | 1.5MBaud |
| 2000 | 2MBaud |
| 12500000 | 12.5MBaud |
Control over UART options. The InvertRX option controls invert of the receive pin. The InvertTX option controls invert of the transmit pin. The HalfDuplex option controls half-duplex (onewire) mode, where both transmit and receive is done on the transmit wire. The Swap option allows the RX and TX pins to be swapped on STM32F7 based boards. NOTE that two bits have moved from this parameter into MAVn_OPTIONS!
Control what protocol Serial9 port should be used for. Note that the Frsky options require external converter hardware. See the wiki for details.
| Value | Meaning |
|---|---|
| -1 | None |
| 1 | MAVLink1 |
| 2 | MAVLink2 |
| 3 | Frsky D |
| 4 | Frsky SPort |
| 5 | GPS |
| 7 | Alexmos Gimbal Serial |
| 8 | Gimbal |
| 9 | Rangefinder |
| 10 | FrSky SPort Passthrough (OpenTX) |
| 11 | Lidar360 |
| 13 | Beacon |
| 14 | Volz servo out |
| 15 | SBus servo out |
| 16 | ESC Telemetry |
| 17 | Devo Telemetry |
| 18 | OpticalFlow |
| 19 | RobotisServo |
| 20 | NMEA Output |
| 21 | WindVane |
| 22 | SLCAN |
| 23 | RCIN |
| 24 | EFI Serial |
| 25 | LTM |
| 26 | RunCam |
| 27 | HottTelem |
| 28 | Scripting |
| 29 | Crossfire VTX |
| 30 | Generator |
| 31 | Winch |
| 32 | MSP |
| 33 | DJI FPV |
| 34 | AirSpeed |
| 35 | ADSB |
| 36 | AHRS |
| 37 | SmartAudio |
| 38 | FETtecOneWire |
| 39 | Torqeedo |
| 40 | AIS |
| 41 | CoDevESC |
| 42 | DisplayPort |
| 43 | MAVLink High Latency |
| 44 | IRC Tramp |
| 45 | DDS XRCE |
| 46 | IMUDATA |
| 48 | PPP |
| 49 | i-BUS Telemetry |
| 50 | IOMCU |
The baud rate used for Serial8. Most stm32-based boards can support rates of up to 1500. If you setup a rate you cannot support and then can't connect to your board you should load a firmware from a different vehicle type. That will reset all your parameters to defaults.
| Value | Meaning |
|---|---|
| 1 | 1200 |
| 2 | 2400 |
| 4 | 4800 |
| 9 | 9600 |
| 19 | 19200 |
| 38 | 38400 |
| 57 | 57600 |
| 111 | 111100 |
| 115 | 115200 |
| 230 | 230400 |
| 256 | 256000 |
| 460 | 460800 |
| 500 | 500000 |
| 921 | 921600 |
| 1500 | 1.5MBaud |
| 2000 | 2MBaud |
| 12500000 | 12.5MBaud |
Control over UART options. The InvertRX option controls invert of the receive pin. The InvertTX option controls invert of the transmit pin. The HalfDuplex option controls half-duplex (onewire) mode, where both transmit and receive is done on the transmit wire. The Swap option allows the RX and TX pins to be swapped on STM32F7 based boards. NOTE that two bits have moved from this parameter into MAVn_OPTIONS!
Default output rate in Hz for all PWM outputs.
DShot output rate for all outputs as a multiple of the loop rate. 0 sets the output rate to be fixed at 1Khz for low loop rates. This value should never be set below 500Hz.
| Value | Meaning |
|---|---|
| 0 | 1Khz |
| 1 | loop-rate |
| 2 | double loop-rate |
| 3 | triple loop-rate |
| 4 | quadruple loop rate |
DShot ESC type for all outputs. The ESC type affects the range of DShot commands available and the bit widths used. None means that no dshot commands will be executed. Some ESC types support Extended DShot Telemetry (EDT) which allows telemetry other than RPM data to be returned when using bi-directional dshot. If you enable EDT you must install EDT capable firmware for correct operation.
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | BLHeli32/Kiss/AM32 |
| 2 | BLHeli_S/BlueJay |
| 3 | BLHeli32/AM32/Kiss+EDT |
| 4 | BLHeli_S/BlueJay+EDT |
Bitmask of outputs which will be available as GPIOs. Any output with either the function set to -1 or with the corresponding bit set in this mask will be available for use as a GPIO pin
Bitmask of scaled passthru output channels which will be set to their trim value during rc failsafe instead of holding their last position before failsafe.
This allows for up to 32 outputs, enabling parameters for outputs above 16
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Trim PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse servo operation. Set to 0 for normal operation. Set to 1 to reverse this output channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
Function assigned to this servo. Setting this to Disabled(0) will setup this output for control by auto missions or MAVLink servo set commands. any other value will enable the corresponding function
| Value | Meaning |
|---|---|
| -1 | GPIO |
| 0 | Disabled |
| 1 | RCPassThru |
| 2 | Flap |
| 3 | FlapAuto |
| 4 | Aileron |
| 6 | Mount1Yaw |
| 7 | Mount1Pitch |
| 8 | Mount1Roll |
| 9 | Mount1Retract |
| 10 | CameraTrigger |
| 12 | Mount2Yaw |
| 13 | Mount2Pitch |
| 14 | Mount2Roll |
| 15 | Mount2Retract |
| 16 | DifferentialSpoilerLeft1 |
| 17 | DifferentialSpoilerRight1 |
| 19 | Elevator |
| 21 | Rudder |
| 22 | SprayerPump |
| 23 | SprayerSpinner |
| 24 | FlaperonLeft |
| 25 | FlaperonRight |
| 26 | GroundSteering |
| 27 | Parachute |
| 28 | Gripper |
| 29 | LandingGear |
| 30 | EngineRunEnable |
| 31 | HeliRSC |
| 32 | HeliTailRSC |
| 33 | Motor1 |
| 34 | Motor2 |
| 35 | Motor3 |
| 36 | Motor4 |
| 37 | Motor5 |
| 38 | Motor6 |
| 39 | Motor7 |
| 40 | Motor8 |
| 41 | TiltMotorsFront |
| 45 | TiltMotorsRear |
| 46 | TiltMotorRearLeft |
| 47 | TiltMotorRearRight |
| 51 | RCIN1 |
| 52 | RCIN2 |
| 53 | RCIN3 |
| 54 | RCIN4 |
| 55 | RCIN5 |
| 56 | RCIN6 |
| 57 | RCIN7 |
| 58 | RCIN8 |
| 59 | RCIN9 |
| 60 | RCIN10 |
| 61 | RCIN11 |
| 62 | RCIN12 |
| 63 | RCIN13 |
| 64 | RCIN14 |
| 65 | RCIN15 |
| 66 | RCIN16 |
| 67 | Ignition |
| 69 | Starter |
| 70 | Throttle |
| 71 | TrackerYaw |
| 72 | TrackerPitch |
| 73 | ThrottleLeft |
| 74 | ThrottleRight |
| 75 | TiltMotorFrontLeft |
| 76 | TiltMotorFrontRight |
| 77 | ElevonLeft |
| 78 | ElevonRight |
| 79 | VTailLeft |
| 80 | VTailRight |
| 81 | BoostThrottle |
| 82 | Motor9 |
| 83 | Motor10 |
| 84 | Motor11 |
| 85 | Motor12 |
| 86 | DifferentialSpoilerLeft2 |
| 87 | DifferentialSpoilerRight2 |
| 88 | Winch |
| 89 | Main Sail |
| 90 | CameraISO |
| 91 | CameraAperture |
| 92 | CameraFocus |
| 93 | CameraShutterSpeed |
| 94 | Script1 |
| 95 | Script2 |
| 96 | Script3 |
| 97 | Script4 |
| 98 | Script5 |
| 99 | Script6 |
| 100 | Script7 |
| 101 | Script8 |
| 102 | Script9 |
| 103 | Script10 |
| 104 | Script11 |
| 105 | Script12 |
| 106 | Script13 |
| 107 | Script14 |
| 108 | Script15 |
| 109 | Script16 |
| 120 | NeoPixel1 |
| 121 | NeoPixel2 |
| 122 | NeoPixel3 |
| 123 | NeoPixel4 |
| 124 | RateRoll |
| 125 | RatePitch |
| 126 | RateThrust |
| 127 | RateYaw |
| 128 | WingSailElevator |
| 129 | ProfiLED1 |
| 130 | ProfiLED2 |
| 131 | ProfiLED3 |
| 132 | ProfiLEDClock |
| 133 | Winch Clutch |
| 134 | SERVOn_MIN |
| 135 | SERVOn_TRIM |
| 136 | SERVOn_MAX |
| 137 | SailMastRotation |
| 138 | Alarm |
| 139 | Alarm Inverted |
| 140 | RCIN1Scaled |
| 141 | RCIN2Scaled |
| 142 | RCIN3Scaled |
| 143 | RCIN4Scaled |
| 144 | RCIN5Scaled |
| 145 | RCIN6Scaled |
| 146 | RCIN7Scaled |
| 147 | RCIN8Scaled |
| 148 | RCIN9Scaled |
| 149 | RCIN10Scaled |
| 150 | RCIN11Scaled |
| 151 | RCIN12Scaled |
| 152 | RCIN13Scaled |
| 153 | RCIN14Scaled |
| 154 | RCIN15Scaled |
| 155 | RCIN16Scaled |
| 180 | CameraZoom |
minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Trim PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse servo operation. Set to 0 for normal operation. Set to 1 to reverse this output channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
Function assigned to this servo. Setting this to Disabled(0) will setup this output for control by auto missions or MAVLink servo set commands. any other value will enable the corresponding function
| Value | Meaning |
|---|---|
| -1 | GPIO |
| 0 | Disabled |
| 1 | RCPassThru |
| 2 | Flap |
| 3 | FlapAuto |
| 4 | Aileron |
| 6 | Mount1Yaw |
| 7 | Mount1Pitch |
| 8 | Mount1Roll |
| 9 | Mount1Retract |
| 10 | CameraTrigger |
| 12 | Mount2Yaw |
| 13 | Mount2Pitch |
| 14 | Mount2Roll |
| 15 | Mount2Retract |
| 16 | DifferentialSpoilerLeft1 |
| 17 | DifferentialSpoilerRight1 |
| 19 | Elevator |
| 21 | Rudder |
| 22 | SprayerPump |
| 23 | SprayerSpinner |
| 24 | FlaperonLeft |
| 25 | FlaperonRight |
| 26 | GroundSteering |
| 27 | Parachute |
| 28 | Gripper |
| 29 | LandingGear |
| 30 | EngineRunEnable |
| 31 | HeliRSC |
| 32 | HeliTailRSC |
| 33 | Motor1 |
| 34 | Motor2 |
| 35 | Motor3 |
| 36 | Motor4 |
| 37 | Motor5 |
| 38 | Motor6 |
| 39 | Motor7 |
| 40 | Motor8 |
| 41 | TiltMotorsFront |
| 45 | TiltMotorsRear |
| 46 | TiltMotorRearLeft |
| 47 | TiltMotorRearRight |
| 51 | RCIN1 |
| 52 | RCIN2 |
| 53 | RCIN3 |
| 54 | RCIN4 |
| 55 | RCIN5 |
| 56 | RCIN6 |
| 57 | RCIN7 |
| 58 | RCIN8 |
| 59 | RCIN9 |
| 60 | RCIN10 |
| 61 | RCIN11 |
| 62 | RCIN12 |
| 63 | RCIN13 |
| 64 | RCIN14 |
| 65 | RCIN15 |
| 66 | RCIN16 |
| 67 | Ignition |
| 69 | Starter |
| 70 | Throttle |
| 71 | TrackerYaw |
| 72 | TrackerPitch |
| 73 | ThrottleLeft |
| 74 | ThrottleRight |
| 75 | TiltMotorFrontLeft |
| 76 | TiltMotorFrontRight |
| 77 | ElevonLeft |
| 78 | ElevonRight |
| 79 | VTailLeft |
| 80 | VTailRight |
| 81 | BoostThrottle |
| 82 | Motor9 |
| 83 | Motor10 |
| 84 | Motor11 |
| 85 | Motor12 |
| 86 | DifferentialSpoilerLeft2 |
| 87 | DifferentialSpoilerRight2 |
| 88 | Winch |
| 89 | Main Sail |
| 90 | CameraISO |
| 91 | CameraAperture |
| 92 | CameraFocus |
| 93 | CameraShutterSpeed |
| 94 | Script1 |
| 95 | Script2 |
| 96 | Script3 |
| 97 | Script4 |
| 98 | Script5 |
| 99 | Script6 |
| 100 | Script7 |
| 101 | Script8 |
| 102 | Script9 |
| 103 | Script10 |
| 104 | Script11 |
| 105 | Script12 |
| 106 | Script13 |
| 107 | Script14 |
| 108 | Script15 |
| 109 | Script16 |
| 120 | NeoPixel1 |
| 121 | NeoPixel2 |
| 122 | NeoPixel3 |
| 123 | NeoPixel4 |
| 124 | RateRoll |
| 125 | RatePitch |
| 126 | RateThrust |
| 127 | RateYaw |
| 128 | WingSailElevator |
| 129 | ProfiLED1 |
| 130 | ProfiLED2 |
| 131 | ProfiLED3 |
| 132 | ProfiLEDClock |
| 133 | Winch Clutch |
| 134 | SERVOn_MIN |
| 135 | SERVOn_TRIM |
| 136 | SERVOn_MAX |
| 137 | SailMastRotation |
| 138 | Alarm |
| 139 | Alarm Inverted |
| 140 | RCIN1Scaled |
| 141 | RCIN2Scaled |
| 142 | RCIN3Scaled |
| 143 | RCIN4Scaled |
| 144 | RCIN5Scaled |
| 145 | RCIN6Scaled |
| 146 | RCIN7Scaled |
| 147 | RCIN8Scaled |
| 148 | RCIN9Scaled |
| 149 | RCIN10Scaled |
| 150 | RCIN11Scaled |
| 151 | RCIN12Scaled |
| 152 | RCIN13Scaled |
| 153 | RCIN14Scaled |
| 154 | RCIN15Scaled |
| 155 | RCIN16Scaled |
| 180 | CameraZoom |
minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Trim PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse servo operation. Set to 0 for normal operation. Set to 1 to reverse this output channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
Function assigned to this servo. Setting this to Disabled(0) will setup this output for control by auto missions or MAVLink servo set commands. any other value will enable the corresponding function
| Value | Meaning |
|---|---|
| -1 | GPIO |
| 0 | Disabled |
| 1 | RCPassThru |
| 2 | Flap |
| 3 | FlapAuto |
| 4 | Aileron |
| 6 | Mount1Yaw |
| 7 | Mount1Pitch |
| 8 | Mount1Roll |
| 9 | Mount1Retract |
| 10 | CameraTrigger |
| 12 | Mount2Yaw |
| 13 | Mount2Pitch |
| 14 | Mount2Roll |
| 15 | Mount2Retract |
| 16 | DifferentialSpoilerLeft1 |
| 17 | DifferentialSpoilerRight1 |
| 19 | Elevator |
| 21 | Rudder |
| 22 | SprayerPump |
| 23 | SprayerSpinner |
| 24 | FlaperonLeft |
| 25 | FlaperonRight |
| 26 | GroundSteering |
| 27 | Parachute |
| 28 | Gripper |
| 29 | LandingGear |
| 30 | EngineRunEnable |
| 31 | HeliRSC |
| 32 | HeliTailRSC |
| 33 | Motor1 |
| 34 | Motor2 |
| 35 | Motor3 |
| 36 | Motor4 |
| 37 | Motor5 |
| 38 | Motor6 |
| 39 | Motor7 |
| 40 | Motor8 |
| 41 | TiltMotorsFront |
| 45 | TiltMotorsRear |
| 46 | TiltMotorRearLeft |
| 47 | TiltMotorRearRight |
| 51 | RCIN1 |
| 52 | RCIN2 |
| 53 | RCIN3 |
| 54 | RCIN4 |
| 55 | RCIN5 |
| 56 | RCIN6 |
| 57 | RCIN7 |
| 58 | RCIN8 |
| 59 | RCIN9 |
| 60 | RCIN10 |
| 61 | RCIN11 |
| 62 | RCIN12 |
| 63 | RCIN13 |
| 64 | RCIN14 |
| 65 | RCIN15 |
| 66 | RCIN16 |
| 67 | Ignition |
| 69 | Starter |
| 70 | Throttle |
| 71 | TrackerYaw |
| 72 | TrackerPitch |
| 73 | ThrottleLeft |
| 74 | ThrottleRight |
| 75 | TiltMotorFrontLeft |
| 76 | TiltMotorFrontRight |
| 77 | ElevonLeft |
| 78 | ElevonRight |
| 79 | VTailLeft |
| 80 | VTailRight |
| 81 | BoostThrottle |
| 82 | Motor9 |
| 83 | Motor10 |
| 84 | Motor11 |
| 85 | Motor12 |
| 86 | DifferentialSpoilerLeft2 |
| 87 | DifferentialSpoilerRight2 |
| 88 | Winch |
| 89 | Main Sail |
| 90 | CameraISO |
| 91 | CameraAperture |
| 92 | CameraFocus |
| 93 | CameraShutterSpeed |
| 94 | Script1 |
| 95 | Script2 |
| 96 | Script3 |
| 97 | Script4 |
| 98 | Script5 |
| 99 | Script6 |
| 100 | Script7 |
| 101 | Script8 |
| 102 | Script9 |
| 103 | Script10 |
| 104 | Script11 |
| 105 | Script12 |
| 106 | Script13 |
| 107 | Script14 |
| 108 | Script15 |
| 109 | Script16 |
| 120 | NeoPixel1 |
| 121 | NeoPixel2 |
| 122 | NeoPixel3 |
| 123 | NeoPixel4 |
| 124 | RateRoll |
| 125 | RatePitch |
| 126 | RateThrust |
| 127 | RateYaw |
| 128 | WingSailElevator |
| 129 | ProfiLED1 |
| 130 | ProfiLED2 |
| 131 | ProfiLED3 |
| 132 | ProfiLEDClock |
| 133 | Winch Clutch |
| 134 | SERVOn_MIN |
| 135 | SERVOn_TRIM |
| 136 | SERVOn_MAX |
| 137 | SailMastRotation |
| 138 | Alarm |
| 139 | Alarm Inverted |
| 140 | RCIN1Scaled |
| 141 | RCIN2Scaled |
| 142 | RCIN3Scaled |
| 143 | RCIN4Scaled |
| 144 | RCIN5Scaled |
| 145 | RCIN6Scaled |
| 146 | RCIN7Scaled |
| 147 | RCIN8Scaled |
| 148 | RCIN9Scaled |
| 149 | RCIN10Scaled |
| 150 | RCIN11Scaled |
| 151 | RCIN12Scaled |
| 152 | RCIN13Scaled |
| 153 | RCIN14Scaled |
| 154 | RCIN15Scaled |
| 155 | RCIN16Scaled |
| 180 | CameraZoom |
minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Trim PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse servo operation. Set to 0 for normal operation. Set to 1 to reverse this output channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
Function assigned to this servo. Setting this to Disabled(0) will setup this output for control by auto missions or MAVLink servo set commands. any other value will enable the corresponding function
| Value | Meaning |
|---|---|
| -1 | GPIO |
| 0 | Disabled |
| 1 | RCPassThru |
| 2 | Flap |
| 3 | FlapAuto |
| 4 | Aileron |
| 6 | Mount1Yaw |
| 7 | Mount1Pitch |
| 8 | Mount1Roll |
| 9 | Mount1Retract |
| 10 | CameraTrigger |
| 12 | Mount2Yaw |
| 13 | Mount2Pitch |
| 14 | Mount2Roll |
| 15 | Mount2Retract |
| 16 | DifferentialSpoilerLeft1 |
| 17 | DifferentialSpoilerRight1 |
| 19 | Elevator |
| 21 | Rudder |
| 22 | SprayerPump |
| 23 | SprayerSpinner |
| 24 | FlaperonLeft |
| 25 | FlaperonRight |
| 26 | GroundSteering |
| 27 | Parachute |
| 28 | Gripper |
| 29 | LandingGear |
| 30 | EngineRunEnable |
| 31 | HeliRSC |
| 32 | HeliTailRSC |
| 33 | Motor1 |
| 34 | Motor2 |
| 35 | Motor3 |
| 36 | Motor4 |
| 37 | Motor5 |
| 38 | Motor6 |
| 39 | Motor7 |
| 40 | Motor8 |
| 41 | TiltMotorsFront |
| 45 | TiltMotorsRear |
| 46 | TiltMotorRearLeft |
| 47 | TiltMotorRearRight |
| 51 | RCIN1 |
| 52 | RCIN2 |
| 53 | RCIN3 |
| 54 | RCIN4 |
| 55 | RCIN5 |
| 56 | RCIN6 |
| 57 | RCIN7 |
| 58 | RCIN8 |
| 59 | RCIN9 |
| 60 | RCIN10 |
| 61 | RCIN11 |
| 62 | RCIN12 |
| 63 | RCIN13 |
| 64 | RCIN14 |
| 65 | RCIN15 |
| 66 | RCIN16 |
| 67 | Ignition |
| 69 | Starter |
| 70 | Throttle |
| 71 | TrackerYaw |
| 72 | TrackerPitch |
| 73 | ThrottleLeft |
| 74 | ThrottleRight |
| 75 | TiltMotorFrontLeft |
| 76 | TiltMotorFrontRight |
| 77 | ElevonLeft |
| 78 | ElevonRight |
| 79 | VTailLeft |
| 80 | VTailRight |
| 81 | BoostThrottle |
| 82 | Motor9 |
| 83 | Motor10 |
| 84 | Motor11 |
| 85 | Motor12 |
| 86 | DifferentialSpoilerLeft2 |
| 87 | DifferentialSpoilerRight2 |
| 88 | Winch |
| 89 | Main Sail |
| 90 | CameraISO |
| 91 | CameraAperture |
| 92 | CameraFocus |
| 93 | CameraShutterSpeed |
| 94 | Script1 |
| 95 | Script2 |
| 96 | Script3 |
| 97 | Script4 |
| 98 | Script5 |
| 99 | Script6 |
| 100 | Script7 |
| 101 | Script8 |
| 102 | Script9 |
| 103 | Script10 |
| 104 | Script11 |
| 105 | Script12 |
| 106 | Script13 |
| 107 | Script14 |
| 108 | Script15 |
| 109 | Script16 |
| 120 | NeoPixel1 |
| 121 | NeoPixel2 |
| 122 | NeoPixel3 |
| 123 | NeoPixel4 |
| 124 | RateRoll |
| 125 | RatePitch |
| 126 | RateThrust |
| 127 | RateYaw |
| 128 | WingSailElevator |
| 129 | ProfiLED1 |
| 130 | ProfiLED2 |
| 131 | ProfiLED3 |
| 132 | ProfiLEDClock |
| 133 | Winch Clutch |
| 134 | SERVOn_MIN |
| 135 | SERVOn_TRIM |
| 136 | SERVOn_MAX |
| 137 | SailMastRotation |
| 138 | Alarm |
| 139 | Alarm Inverted |
| 140 | RCIN1Scaled |
| 141 | RCIN2Scaled |
| 142 | RCIN3Scaled |
| 143 | RCIN4Scaled |
| 144 | RCIN5Scaled |
| 145 | RCIN6Scaled |
| 146 | RCIN7Scaled |
| 147 | RCIN8Scaled |
| 148 | RCIN9Scaled |
| 149 | RCIN10Scaled |
| 150 | RCIN11Scaled |
| 151 | RCIN12Scaled |
| 152 | RCIN13Scaled |
| 153 | RCIN14Scaled |
| 154 | RCIN15Scaled |
| 155 | RCIN16Scaled |
| 180 | CameraZoom |
minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Trim PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse servo operation. Set to 0 for normal operation. Set to 1 to reverse this output channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
Function assigned to this servo. Setting this to Disabled(0) will setup this output for control by auto missions or MAVLink servo set commands. any other value will enable the corresponding function
| Value | Meaning |
|---|---|
| -1 | GPIO |
| 0 | Disabled |
| 1 | RCPassThru |
| 2 | Flap |
| 3 | FlapAuto |
| 4 | Aileron |
| 6 | Mount1Yaw |
| 7 | Mount1Pitch |
| 8 | Mount1Roll |
| 9 | Mount1Retract |
| 10 | CameraTrigger |
| 12 | Mount2Yaw |
| 13 | Mount2Pitch |
| 14 | Mount2Roll |
| 15 | Mount2Retract |
| 16 | DifferentialSpoilerLeft1 |
| 17 | DifferentialSpoilerRight1 |
| 19 | Elevator |
| 21 | Rudder |
| 22 | SprayerPump |
| 23 | SprayerSpinner |
| 24 | FlaperonLeft |
| 25 | FlaperonRight |
| 26 | GroundSteering |
| 27 | Parachute |
| 28 | Gripper |
| 29 | LandingGear |
| 30 | EngineRunEnable |
| 31 | HeliRSC |
| 32 | HeliTailRSC |
| 33 | Motor1 |
| 34 | Motor2 |
| 35 | Motor3 |
| 36 | Motor4 |
| 37 | Motor5 |
| 38 | Motor6 |
| 39 | Motor7 |
| 40 | Motor8 |
| 41 | TiltMotorsFront |
| 45 | TiltMotorsRear |
| 46 | TiltMotorRearLeft |
| 47 | TiltMotorRearRight |
| 51 | RCIN1 |
| 52 | RCIN2 |
| 53 | RCIN3 |
| 54 | RCIN4 |
| 55 | RCIN5 |
| 56 | RCIN6 |
| 57 | RCIN7 |
| 58 | RCIN8 |
| 59 | RCIN9 |
| 60 | RCIN10 |
| 61 | RCIN11 |
| 62 | RCIN12 |
| 63 | RCIN13 |
| 64 | RCIN14 |
| 65 | RCIN15 |
| 66 | RCIN16 |
| 67 | Ignition |
| 69 | Starter |
| 70 | Throttle |
| 71 | TrackerYaw |
| 72 | TrackerPitch |
| 73 | ThrottleLeft |
| 74 | ThrottleRight |
| 75 | TiltMotorFrontLeft |
| 76 | TiltMotorFrontRight |
| 77 | ElevonLeft |
| 78 | ElevonRight |
| 79 | VTailLeft |
| 80 | VTailRight |
| 81 | BoostThrottle |
| 82 | Motor9 |
| 83 | Motor10 |
| 84 | Motor11 |
| 85 | Motor12 |
| 86 | DifferentialSpoilerLeft2 |
| 87 | DifferentialSpoilerRight2 |
| 88 | Winch |
| 89 | Main Sail |
| 90 | CameraISO |
| 91 | CameraAperture |
| 92 | CameraFocus |
| 93 | CameraShutterSpeed |
| 94 | Script1 |
| 95 | Script2 |
| 96 | Script3 |
| 97 | Script4 |
| 98 | Script5 |
| 99 | Script6 |
| 100 | Script7 |
| 101 | Script8 |
| 102 | Script9 |
| 103 | Script10 |
| 104 | Script11 |
| 105 | Script12 |
| 106 | Script13 |
| 107 | Script14 |
| 108 | Script15 |
| 109 | Script16 |
| 120 | NeoPixel1 |
| 121 | NeoPixel2 |
| 122 | NeoPixel3 |
| 123 | NeoPixel4 |
| 124 | RateRoll |
| 125 | RatePitch |
| 126 | RateThrust |
| 127 | RateYaw |
| 128 | WingSailElevator |
| 129 | ProfiLED1 |
| 130 | ProfiLED2 |
| 131 | ProfiLED3 |
| 132 | ProfiLEDClock |
| 133 | Winch Clutch |
| 134 | SERVOn_MIN |
| 135 | SERVOn_TRIM |
| 136 | SERVOn_MAX |
| 137 | SailMastRotation |
| 138 | Alarm |
| 139 | Alarm Inverted |
| 140 | RCIN1Scaled |
| 141 | RCIN2Scaled |
| 142 | RCIN3Scaled |
| 143 | RCIN4Scaled |
| 144 | RCIN5Scaled |
| 145 | RCIN6Scaled |
| 146 | RCIN7Scaled |
| 147 | RCIN8Scaled |
| 148 | RCIN9Scaled |
| 149 | RCIN10Scaled |
| 150 | RCIN11Scaled |
| 151 | RCIN12Scaled |
| 152 | RCIN13Scaled |
| 153 | RCIN14Scaled |
| 154 | RCIN15Scaled |
| 155 | RCIN16Scaled |
| 180 | CameraZoom |
minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Trim PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse servo operation. Set to 0 for normal operation. Set to 1 to reverse this output channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
Function assigned to this servo. Setting this to Disabled(0) will setup this output for control by auto missions or MAVLink servo set commands. any other value will enable the corresponding function
| Value | Meaning |
|---|---|
| -1 | GPIO |
| 0 | Disabled |
| 1 | RCPassThru |
| 2 | Flap |
| 3 | FlapAuto |
| 4 | Aileron |
| 6 | Mount1Yaw |
| 7 | Mount1Pitch |
| 8 | Mount1Roll |
| 9 | Mount1Retract |
| 10 | CameraTrigger |
| 12 | Mount2Yaw |
| 13 | Mount2Pitch |
| 14 | Mount2Roll |
| 15 | Mount2Retract |
| 16 | DifferentialSpoilerLeft1 |
| 17 | DifferentialSpoilerRight1 |
| 19 | Elevator |
| 21 | Rudder |
| 22 | SprayerPump |
| 23 | SprayerSpinner |
| 24 | FlaperonLeft |
| 25 | FlaperonRight |
| 26 | GroundSteering |
| 27 | Parachute |
| 28 | Gripper |
| 29 | LandingGear |
| 30 | EngineRunEnable |
| 31 | HeliRSC |
| 32 | HeliTailRSC |
| 33 | Motor1 |
| 34 | Motor2 |
| 35 | Motor3 |
| 36 | Motor4 |
| 37 | Motor5 |
| 38 | Motor6 |
| 39 | Motor7 |
| 40 | Motor8 |
| 41 | TiltMotorsFront |
| 45 | TiltMotorsRear |
| 46 | TiltMotorRearLeft |
| 47 | TiltMotorRearRight |
| 51 | RCIN1 |
| 52 | RCIN2 |
| 53 | RCIN3 |
| 54 | RCIN4 |
| 55 | RCIN5 |
| 56 | RCIN6 |
| 57 | RCIN7 |
| 58 | RCIN8 |
| 59 | RCIN9 |
| 60 | RCIN10 |
| 61 | RCIN11 |
| 62 | RCIN12 |
| 63 | RCIN13 |
| 64 | RCIN14 |
| 65 | RCIN15 |
| 66 | RCIN16 |
| 67 | Ignition |
| 69 | Starter |
| 70 | Throttle |
| 71 | TrackerYaw |
| 72 | TrackerPitch |
| 73 | ThrottleLeft |
| 74 | ThrottleRight |
| 75 | TiltMotorFrontLeft |
| 76 | TiltMotorFrontRight |
| 77 | ElevonLeft |
| 78 | ElevonRight |
| 79 | VTailLeft |
| 80 | VTailRight |
| 81 | BoostThrottle |
| 82 | Motor9 |
| 83 | Motor10 |
| 84 | Motor11 |
| 85 | Motor12 |
| 86 | DifferentialSpoilerLeft2 |
| 87 | DifferentialSpoilerRight2 |
| 88 | Winch |
| 89 | Main Sail |
| 90 | CameraISO |
| 91 | CameraAperture |
| 92 | CameraFocus |
| 93 | CameraShutterSpeed |
| 94 | Script1 |
| 95 | Script2 |
| 96 | Script3 |
| 97 | Script4 |
| 98 | Script5 |
| 99 | Script6 |
| 100 | Script7 |
| 101 | Script8 |
| 102 | Script9 |
| 103 | Script10 |
| 104 | Script11 |
| 105 | Script12 |
| 106 | Script13 |
| 107 | Script14 |
| 108 | Script15 |
| 109 | Script16 |
| 120 | NeoPixel1 |
| 121 | NeoPixel2 |
| 122 | NeoPixel3 |
| 123 | NeoPixel4 |
| 124 | RateRoll |
| 125 | RatePitch |
| 126 | RateThrust |
| 127 | RateYaw |
| 128 | WingSailElevator |
| 129 | ProfiLED1 |
| 130 | ProfiLED2 |
| 131 | ProfiLED3 |
| 132 | ProfiLEDClock |
| 133 | Winch Clutch |
| 134 | SERVOn_MIN |
| 135 | SERVOn_TRIM |
| 136 | SERVOn_MAX |
| 137 | SailMastRotation |
| 138 | Alarm |
| 139 | Alarm Inverted |
| 140 | RCIN1Scaled |
| 141 | RCIN2Scaled |
| 142 | RCIN3Scaled |
| 143 | RCIN4Scaled |
| 144 | RCIN5Scaled |
| 145 | RCIN6Scaled |
| 146 | RCIN7Scaled |
| 147 | RCIN8Scaled |
| 148 | RCIN9Scaled |
| 149 | RCIN10Scaled |
| 150 | RCIN11Scaled |
| 151 | RCIN12Scaled |
| 152 | RCIN13Scaled |
| 153 | RCIN14Scaled |
| 154 | RCIN15Scaled |
| 155 | RCIN16Scaled |
| 180 | CameraZoom |
minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Trim PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse servo operation. Set to 0 for normal operation. Set to 1 to reverse this output channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
Function assigned to this servo. Setting this to Disabled(0) will setup this output for control by auto missions or MAVLink servo set commands. any other value will enable the corresponding function
| Value | Meaning |
|---|---|
| -1 | GPIO |
| 0 | Disabled |
| 1 | RCPassThru |
| 2 | Flap |
| 3 | FlapAuto |
| 4 | Aileron |
| 6 | Mount1Yaw |
| 7 | Mount1Pitch |
| 8 | Mount1Roll |
| 9 | Mount1Retract |
| 10 | CameraTrigger |
| 12 | Mount2Yaw |
| 13 | Mount2Pitch |
| 14 | Mount2Roll |
| 15 | Mount2Retract |
| 16 | DifferentialSpoilerLeft1 |
| 17 | DifferentialSpoilerRight1 |
| 19 | Elevator |
| 21 | Rudder |
| 22 | SprayerPump |
| 23 | SprayerSpinner |
| 24 | FlaperonLeft |
| 25 | FlaperonRight |
| 26 | GroundSteering |
| 27 | Parachute |
| 28 | Gripper |
| 29 | LandingGear |
| 30 | EngineRunEnable |
| 31 | HeliRSC |
| 32 | HeliTailRSC |
| 33 | Motor1 |
| 34 | Motor2 |
| 35 | Motor3 |
| 36 | Motor4 |
| 37 | Motor5 |
| 38 | Motor6 |
| 39 | Motor7 |
| 40 | Motor8 |
| 41 | TiltMotorsFront |
| 45 | TiltMotorsRear |
| 46 | TiltMotorRearLeft |
| 47 | TiltMotorRearRight |
| 51 | RCIN1 |
| 52 | RCIN2 |
| 53 | RCIN3 |
| 54 | RCIN4 |
| 55 | RCIN5 |
| 56 | RCIN6 |
| 57 | RCIN7 |
| 58 | RCIN8 |
| 59 | RCIN9 |
| 60 | RCIN10 |
| 61 | RCIN11 |
| 62 | RCIN12 |
| 63 | RCIN13 |
| 64 | RCIN14 |
| 65 | RCIN15 |
| 66 | RCIN16 |
| 67 | Ignition |
| 69 | Starter |
| 70 | Throttle |
| 71 | TrackerYaw |
| 72 | TrackerPitch |
| 73 | ThrottleLeft |
| 74 | ThrottleRight |
| 75 | TiltMotorFrontLeft |
| 76 | TiltMotorFrontRight |
| 77 | ElevonLeft |
| 78 | ElevonRight |
| 79 | VTailLeft |
| 80 | VTailRight |
| 81 | BoostThrottle |
| 82 | Motor9 |
| 83 | Motor10 |
| 84 | Motor11 |
| 85 | Motor12 |
| 86 | DifferentialSpoilerLeft2 |
| 87 | DifferentialSpoilerRight2 |
| 88 | Winch |
| 89 | Main Sail |
| 90 | CameraISO |
| 91 | CameraAperture |
| 92 | CameraFocus |
| 93 | CameraShutterSpeed |
| 94 | Script1 |
| 95 | Script2 |
| 96 | Script3 |
| 97 | Script4 |
| 98 | Script5 |
| 99 | Script6 |
| 100 | Script7 |
| 101 | Script8 |
| 102 | Script9 |
| 103 | Script10 |
| 104 | Script11 |
| 105 | Script12 |
| 106 | Script13 |
| 107 | Script14 |
| 108 | Script15 |
| 109 | Script16 |
| 120 | NeoPixel1 |
| 121 | NeoPixel2 |
| 122 | NeoPixel3 |
| 123 | NeoPixel4 |
| 124 | RateRoll |
| 125 | RatePitch |
| 126 | RateThrust |
| 127 | RateYaw |
| 128 | WingSailElevator |
| 129 | ProfiLED1 |
| 130 | ProfiLED2 |
| 131 | ProfiLED3 |
| 132 | ProfiLEDClock |
| 133 | Winch Clutch |
| 134 | SERVOn_MIN |
| 135 | SERVOn_TRIM |
| 136 | SERVOn_MAX |
| 137 | SailMastRotation |
| 138 | Alarm |
| 139 | Alarm Inverted |
| 140 | RCIN1Scaled |
| 141 | RCIN2Scaled |
| 142 | RCIN3Scaled |
| 143 | RCIN4Scaled |
| 144 | RCIN5Scaled |
| 145 | RCIN6Scaled |
| 146 | RCIN7Scaled |
| 147 | RCIN8Scaled |
| 148 | RCIN9Scaled |
| 149 | RCIN10Scaled |
| 150 | RCIN11Scaled |
| 151 | RCIN12Scaled |
| 152 | RCIN13Scaled |
| 153 | RCIN14Scaled |
| 154 | RCIN15Scaled |
| 155 | RCIN16Scaled |
| 180 | CameraZoom |
minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Trim PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse servo operation. Set to 0 for normal operation. Set to 1 to reverse this output channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
Function assigned to this servo. Setting this to Disabled(0) will setup this output for control by auto missions or MAVLink servo set commands. any other value will enable the corresponding function
| Value | Meaning |
|---|---|
| -1 | GPIO |
| 0 | Disabled |
| 1 | RCPassThru |
| 2 | Flap |
| 3 | FlapAuto |
| 4 | Aileron |
| 6 | Mount1Yaw |
| 7 | Mount1Pitch |
| 8 | Mount1Roll |
| 9 | Mount1Retract |
| 10 | CameraTrigger |
| 12 | Mount2Yaw |
| 13 | Mount2Pitch |
| 14 | Mount2Roll |
| 15 | Mount2Retract |
| 16 | DifferentialSpoilerLeft1 |
| 17 | DifferentialSpoilerRight1 |
| 19 | Elevator |
| 21 | Rudder |
| 22 | SprayerPump |
| 23 | SprayerSpinner |
| 24 | FlaperonLeft |
| 25 | FlaperonRight |
| 26 | GroundSteering |
| 27 | Parachute |
| 28 | Gripper |
| 29 | LandingGear |
| 30 | EngineRunEnable |
| 31 | HeliRSC |
| 32 | HeliTailRSC |
| 33 | Motor1 |
| 34 | Motor2 |
| 35 | Motor3 |
| 36 | Motor4 |
| 37 | Motor5 |
| 38 | Motor6 |
| 39 | Motor7 |
| 40 | Motor8 |
| 41 | TiltMotorsFront |
| 45 | TiltMotorsRear |
| 46 | TiltMotorRearLeft |
| 47 | TiltMotorRearRight |
| 51 | RCIN1 |
| 52 | RCIN2 |
| 53 | RCIN3 |
| 54 | RCIN4 |
| 55 | RCIN5 |
| 56 | RCIN6 |
| 57 | RCIN7 |
| 58 | RCIN8 |
| 59 | RCIN9 |
| 60 | RCIN10 |
| 61 | RCIN11 |
| 62 | RCIN12 |
| 63 | RCIN13 |
| 64 | RCIN14 |
| 65 | RCIN15 |
| 66 | RCIN16 |
| 67 | Ignition |
| 69 | Starter |
| 70 | Throttle |
| 71 | TrackerYaw |
| 72 | TrackerPitch |
| 73 | ThrottleLeft |
| 74 | ThrottleRight |
| 75 | TiltMotorFrontLeft |
| 76 | TiltMotorFrontRight |
| 77 | ElevonLeft |
| 78 | ElevonRight |
| 79 | VTailLeft |
| 80 | VTailRight |
| 81 | BoostThrottle |
| 82 | Motor9 |
| 83 | Motor10 |
| 84 | Motor11 |
| 85 | Motor12 |
| 86 | DifferentialSpoilerLeft2 |
| 87 | DifferentialSpoilerRight2 |
| 88 | Winch |
| 89 | Main Sail |
| 90 | CameraISO |
| 91 | CameraAperture |
| 92 | CameraFocus |
| 93 | CameraShutterSpeed |
| 94 | Script1 |
| 95 | Script2 |
| 96 | Script3 |
| 97 | Script4 |
| 98 | Script5 |
| 99 | Script6 |
| 100 | Script7 |
| 101 | Script8 |
| 102 | Script9 |
| 103 | Script10 |
| 104 | Script11 |
| 105 | Script12 |
| 106 | Script13 |
| 107 | Script14 |
| 108 | Script15 |
| 109 | Script16 |
| 120 | NeoPixel1 |
| 121 | NeoPixel2 |
| 122 | NeoPixel3 |
| 123 | NeoPixel4 |
| 124 | RateRoll |
| 125 | RatePitch |
| 126 | RateThrust |
| 127 | RateYaw |
| 128 | WingSailElevator |
| 129 | ProfiLED1 |
| 130 | ProfiLED2 |
| 131 | ProfiLED3 |
| 132 | ProfiLEDClock |
| 133 | Winch Clutch |
| 134 | SERVOn_MIN |
| 135 | SERVOn_TRIM |
| 136 | SERVOn_MAX |
| 137 | SailMastRotation |
| 138 | Alarm |
| 139 | Alarm Inverted |
| 140 | RCIN1Scaled |
| 141 | RCIN2Scaled |
| 142 | RCIN3Scaled |
| 143 | RCIN4Scaled |
| 144 | RCIN5Scaled |
| 145 | RCIN6Scaled |
| 146 | RCIN7Scaled |
| 147 | RCIN8Scaled |
| 148 | RCIN9Scaled |
| 149 | RCIN10Scaled |
| 150 | RCIN11Scaled |
| 151 | RCIN12Scaled |
| 152 | RCIN13Scaled |
| 153 | RCIN14Scaled |
| 154 | RCIN15Scaled |
| 155 | RCIN16Scaled |
| 180 | CameraZoom |
minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Trim PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse servo operation. Set to 0 for normal operation. Set to 1 to reverse this output channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
Function assigned to this servo. Setting this to Disabled(0) will setup this output for control by auto missions or MAVLink servo set commands. any other value will enable the corresponding function
| Value | Meaning |
|---|---|
| -1 | GPIO |
| 0 | Disabled |
| 1 | RCPassThru |
| 2 | Flap |
| 3 | FlapAuto |
| 4 | Aileron |
| 6 | Mount1Yaw |
| 7 | Mount1Pitch |
| 8 | Mount1Roll |
| 9 | Mount1Retract |
| 10 | CameraTrigger |
| 12 | Mount2Yaw |
| 13 | Mount2Pitch |
| 14 | Mount2Roll |
| 15 | Mount2Retract |
| 16 | DifferentialSpoilerLeft1 |
| 17 | DifferentialSpoilerRight1 |
| 19 | Elevator |
| 21 | Rudder |
| 22 | SprayerPump |
| 23 | SprayerSpinner |
| 24 | FlaperonLeft |
| 25 | FlaperonRight |
| 26 | GroundSteering |
| 27 | Parachute |
| 28 | Gripper |
| 29 | LandingGear |
| 30 | EngineRunEnable |
| 31 | HeliRSC |
| 32 | HeliTailRSC |
| 33 | Motor1 |
| 34 | Motor2 |
| 35 | Motor3 |
| 36 | Motor4 |
| 37 | Motor5 |
| 38 | Motor6 |
| 39 | Motor7 |
| 40 | Motor8 |
| 41 | TiltMotorsFront |
| 45 | TiltMotorsRear |
| 46 | TiltMotorRearLeft |
| 47 | TiltMotorRearRight |
| 51 | RCIN1 |
| 52 | RCIN2 |
| 53 | RCIN3 |
| 54 | RCIN4 |
| 55 | RCIN5 |
| 56 | RCIN6 |
| 57 | RCIN7 |
| 58 | RCIN8 |
| 59 | RCIN9 |
| 60 | RCIN10 |
| 61 | RCIN11 |
| 62 | RCIN12 |
| 63 | RCIN13 |
| 64 | RCIN14 |
| 65 | RCIN15 |
| 66 | RCIN16 |
| 67 | Ignition |
| 69 | Starter |
| 70 | Throttle |
| 71 | TrackerYaw |
| 72 | TrackerPitch |
| 73 | ThrottleLeft |
| 74 | ThrottleRight |
| 75 | TiltMotorFrontLeft |
| 76 | TiltMotorFrontRight |
| 77 | ElevonLeft |
| 78 | ElevonRight |
| 79 | VTailLeft |
| 80 | VTailRight |
| 81 | BoostThrottle |
| 82 | Motor9 |
| 83 | Motor10 |
| 84 | Motor11 |
| 85 | Motor12 |
| 86 | DifferentialSpoilerLeft2 |
| 87 | DifferentialSpoilerRight2 |
| 88 | Winch |
| 89 | Main Sail |
| 90 | CameraISO |
| 91 | CameraAperture |
| 92 | CameraFocus |
| 93 | CameraShutterSpeed |
| 94 | Script1 |
| 95 | Script2 |
| 96 | Script3 |
| 97 | Script4 |
| 98 | Script5 |
| 99 | Script6 |
| 100 | Script7 |
| 101 | Script8 |
| 102 | Script9 |
| 103 | Script10 |
| 104 | Script11 |
| 105 | Script12 |
| 106 | Script13 |
| 107 | Script14 |
| 108 | Script15 |
| 109 | Script16 |
| 120 | NeoPixel1 |
| 121 | NeoPixel2 |
| 122 | NeoPixel3 |
| 123 | NeoPixel4 |
| 124 | RateRoll |
| 125 | RatePitch |
| 126 | RateThrust |
| 127 | RateYaw |
| 128 | WingSailElevator |
| 129 | ProfiLED1 |
| 130 | ProfiLED2 |
| 131 | ProfiLED3 |
| 132 | ProfiLEDClock |
| 133 | Winch Clutch |
| 134 | SERVOn_MIN |
| 135 | SERVOn_TRIM |
| 136 | SERVOn_MAX |
| 137 | SailMastRotation |
| 138 | Alarm |
| 139 | Alarm Inverted |
| 140 | RCIN1Scaled |
| 141 | RCIN2Scaled |
| 142 | RCIN3Scaled |
| 143 | RCIN4Scaled |
| 144 | RCIN5Scaled |
| 145 | RCIN6Scaled |
| 146 | RCIN7Scaled |
| 147 | RCIN8Scaled |
| 148 | RCIN9Scaled |
| 149 | RCIN10Scaled |
| 150 | RCIN11Scaled |
| 151 | RCIN12Scaled |
| 152 | RCIN13Scaled |
| 153 | RCIN14Scaled |
| 154 | RCIN15Scaled |
| 155 | RCIN16Scaled |
| 180 | CameraZoom |
minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Trim PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse servo operation. Set to 0 for normal operation. Set to 1 to reverse this output channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
Function assigned to this servo. Setting this to Disabled(0) will setup this output for control by auto missions or MAVLink servo set commands. any other value will enable the corresponding function
| Value | Meaning |
|---|---|
| -1 | GPIO |
| 0 | Disabled |
| 1 | RCPassThru |
| 2 | Flap |
| 3 | FlapAuto |
| 4 | Aileron |
| 6 | Mount1Yaw |
| 7 | Mount1Pitch |
| 8 | Mount1Roll |
| 9 | Mount1Retract |
| 10 | CameraTrigger |
| 12 | Mount2Yaw |
| 13 | Mount2Pitch |
| 14 | Mount2Roll |
| 15 | Mount2Retract |
| 16 | DifferentialSpoilerLeft1 |
| 17 | DifferentialSpoilerRight1 |
| 19 | Elevator |
| 21 | Rudder |
| 22 | SprayerPump |
| 23 | SprayerSpinner |
| 24 | FlaperonLeft |
| 25 | FlaperonRight |
| 26 | GroundSteering |
| 27 | Parachute |
| 28 | Gripper |
| 29 | LandingGear |
| 30 | EngineRunEnable |
| 31 | HeliRSC |
| 32 | HeliTailRSC |
| 33 | Motor1 |
| 34 | Motor2 |
| 35 | Motor3 |
| 36 | Motor4 |
| 37 | Motor5 |
| 38 | Motor6 |
| 39 | Motor7 |
| 40 | Motor8 |
| 41 | TiltMotorsFront |
| 45 | TiltMotorsRear |
| 46 | TiltMotorRearLeft |
| 47 | TiltMotorRearRight |
| 51 | RCIN1 |
| 52 | RCIN2 |
| 53 | RCIN3 |
| 54 | RCIN4 |
| 55 | RCIN5 |
| 56 | RCIN6 |
| 57 | RCIN7 |
| 58 | RCIN8 |
| 59 | RCIN9 |
| 60 | RCIN10 |
| 61 | RCIN11 |
| 62 | RCIN12 |
| 63 | RCIN13 |
| 64 | RCIN14 |
| 65 | RCIN15 |
| 66 | RCIN16 |
| 67 | Ignition |
| 69 | Starter |
| 70 | Throttle |
| 71 | TrackerYaw |
| 72 | TrackerPitch |
| 73 | ThrottleLeft |
| 74 | ThrottleRight |
| 75 | TiltMotorFrontLeft |
| 76 | TiltMotorFrontRight |
| 77 | ElevonLeft |
| 78 | ElevonRight |
| 79 | VTailLeft |
| 80 | VTailRight |
| 81 | BoostThrottle |
| 82 | Motor9 |
| 83 | Motor10 |
| 84 | Motor11 |
| 85 | Motor12 |
| 86 | DifferentialSpoilerLeft2 |
| 87 | DifferentialSpoilerRight2 |
| 88 | Winch |
| 89 | Main Sail |
| 90 | CameraISO |
| 91 | CameraAperture |
| 92 | CameraFocus |
| 93 | CameraShutterSpeed |
| 94 | Script1 |
| 95 | Script2 |
| 96 | Script3 |
| 97 | Script4 |
| 98 | Script5 |
| 99 | Script6 |
| 100 | Script7 |
| 101 | Script8 |
| 102 | Script9 |
| 103 | Script10 |
| 104 | Script11 |
| 105 | Script12 |
| 106 | Script13 |
| 107 | Script14 |
| 108 | Script15 |
| 109 | Script16 |
| 120 | NeoPixel1 |
| 121 | NeoPixel2 |
| 122 | NeoPixel3 |
| 123 | NeoPixel4 |
| 124 | RateRoll |
| 125 | RatePitch |
| 126 | RateThrust |
| 127 | RateYaw |
| 128 | WingSailElevator |
| 129 | ProfiLED1 |
| 130 | ProfiLED2 |
| 131 | ProfiLED3 |
| 132 | ProfiLEDClock |
| 133 | Winch Clutch |
| 134 | SERVOn_MIN |
| 135 | SERVOn_TRIM |
| 136 | SERVOn_MAX |
| 137 | SailMastRotation |
| 138 | Alarm |
| 139 | Alarm Inverted |
| 140 | RCIN1Scaled |
| 141 | RCIN2Scaled |
| 142 | RCIN3Scaled |
| 143 | RCIN4Scaled |
| 144 | RCIN5Scaled |
| 145 | RCIN6Scaled |
| 146 | RCIN7Scaled |
| 147 | RCIN8Scaled |
| 148 | RCIN9Scaled |
| 149 | RCIN10Scaled |
| 150 | RCIN11Scaled |
| 151 | RCIN12Scaled |
| 152 | RCIN13Scaled |
| 153 | RCIN14Scaled |
| 154 | RCIN15Scaled |
| 155 | RCIN16Scaled |
| 180 | CameraZoom |
minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Trim PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse servo operation. Set to 0 for normal operation. Set to 1 to reverse this output channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
Function assigned to this servo. Setting this to Disabled(0) will setup this output for control by auto missions or MAVLink servo set commands. any other value will enable the corresponding function
| Value | Meaning |
|---|---|
| -1 | GPIO |
| 0 | Disabled |
| 1 | RCPassThru |
| 2 | Flap |
| 3 | FlapAuto |
| 4 | Aileron |
| 6 | Mount1Yaw |
| 7 | Mount1Pitch |
| 8 | Mount1Roll |
| 9 | Mount1Retract |
| 10 | CameraTrigger |
| 12 | Mount2Yaw |
| 13 | Mount2Pitch |
| 14 | Mount2Roll |
| 15 | Mount2Retract |
| 16 | DifferentialSpoilerLeft1 |
| 17 | DifferentialSpoilerRight1 |
| 19 | Elevator |
| 21 | Rudder |
| 22 | SprayerPump |
| 23 | SprayerSpinner |
| 24 | FlaperonLeft |
| 25 | FlaperonRight |
| 26 | GroundSteering |
| 27 | Parachute |
| 28 | Gripper |
| 29 | LandingGear |
| 30 | EngineRunEnable |
| 31 | HeliRSC |
| 32 | HeliTailRSC |
| 33 | Motor1 |
| 34 | Motor2 |
| 35 | Motor3 |
| 36 | Motor4 |
| 37 | Motor5 |
| 38 | Motor6 |
| 39 | Motor7 |
| 40 | Motor8 |
| 41 | TiltMotorsFront |
| 45 | TiltMotorsRear |
| 46 | TiltMotorRearLeft |
| 47 | TiltMotorRearRight |
| 51 | RCIN1 |
| 52 | RCIN2 |
| 53 | RCIN3 |
| 54 | RCIN4 |
| 55 | RCIN5 |
| 56 | RCIN6 |
| 57 | RCIN7 |
| 58 | RCIN8 |
| 59 | RCIN9 |
| 60 | RCIN10 |
| 61 | RCIN11 |
| 62 | RCIN12 |
| 63 | RCIN13 |
| 64 | RCIN14 |
| 65 | RCIN15 |
| 66 | RCIN16 |
| 67 | Ignition |
| 69 | Starter |
| 70 | Throttle |
| 71 | TrackerYaw |
| 72 | TrackerPitch |
| 73 | ThrottleLeft |
| 74 | ThrottleRight |
| 75 | TiltMotorFrontLeft |
| 76 | TiltMotorFrontRight |
| 77 | ElevonLeft |
| 78 | ElevonRight |
| 79 | VTailLeft |
| 80 | VTailRight |
| 81 | BoostThrottle |
| 82 | Motor9 |
| 83 | Motor10 |
| 84 | Motor11 |
| 85 | Motor12 |
| 86 | DifferentialSpoilerLeft2 |
| 87 | DifferentialSpoilerRight2 |
| 88 | Winch |
| 89 | Main Sail |
| 90 | CameraISO |
| 91 | CameraAperture |
| 92 | CameraFocus |
| 93 | CameraShutterSpeed |
| 94 | Script1 |
| 95 | Script2 |
| 96 | Script3 |
| 97 | Script4 |
| 98 | Script5 |
| 99 | Script6 |
| 100 | Script7 |
| 101 | Script8 |
| 102 | Script9 |
| 103 | Script10 |
| 104 | Script11 |
| 105 | Script12 |
| 106 | Script13 |
| 107 | Script14 |
| 108 | Script15 |
| 109 | Script16 |
| 120 | NeoPixel1 |
| 121 | NeoPixel2 |
| 122 | NeoPixel3 |
| 123 | NeoPixel4 |
| 124 | RateRoll |
| 125 | RatePitch |
| 126 | RateThrust |
| 127 | RateYaw |
| 128 | WingSailElevator |
| 129 | ProfiLED1 |
| 130 | ProfiLED2 |
| 131 | ProfiLED3 |
| 132 | ProfiLEDClock |
| 133 | Winch Clutch |
| 134 | SERVOn_MIN |
| 135 | SERVOn_TRIM |
| 136 | SERVOn_MAX |
| 137 | SailMastRotation |
| 138 | Alarm |
| 139 | Alarm Inverted |
| 140 | RCIN1Scaled |
| 141 | RCIN2Scaled |
| 142 | RCIN3Scaled |
| 143 | RCIN4Scaled |
| 144 | RCIN5Scaled |
| 145 | RCIN6Scaled |
| 146 | RCIN7Scaled |
| 147 | RCIN8Scaled |
| 148 | RCIN9Scaled |
| 149 | RCIN10Scaled |
| 150 | RCIN11Scaled |
| 151 | RCIN12Scaled |
| 152 | RCIN13Scaled |
| 153 | RCIN14Scaled |
| 154 | RCIN15Scaled |
| 155 | RCIN16Scaled |
| 180 | CameraZoom |
minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Trim PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse servo operation. Set to 0 for normal operation. Set to 1 to reverse this output channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
Function assigned to this servo. Setting this to Disabled(0) will setup this output for control by auto missions or MAVLink servo set commands. any other value will enable the corresponding function
| Value | Meaning |
|---|---|
| -1 | GPIO |
| 0 | Disabled |
| 1 | RCPassThru |
| 2 | Flap |
| 3 | FlapAuto |
| 4 | Aileron |
| 6 | Mount1Yaw |
| 7 | Mount1Pitch |
| 8 | Mount1Roll |
| 9 | Mount1Retract |
| 10 | CameraTrigger |
| 12 | Mount2Yaw |
| 13 | Mount2Pitch |
| 14 | Mount2Roll |
| 15 | Mount2Retract |
| 16 | DifferentialSpoilerLeft1 |
| 17 | DifferentialSpoilerRight1 |
| 19 | Elevator |
| 21 | Rudder |
| 22 | SprayerPump |
| 23 | SprayerSpinner |
| 24 | FlaperonLeft |
| 25 | FlaperonRight |
| 26 | GroundSteering |
| 27 | Parachute |
| 28 | Gripper |
| 29 | LandingGear |
| 30 | EngineRunEnable |
| 31 | HeliRSC |
| 32 | HeliTailRSC |
| 33 | Motor1 |
| 34 | Motor2 |
| 35 | Motor3 |
| 36 | Motor4 |
| 37 | Motor5 |
| 38 | Motor6 |
| 39 | Motor7 |
| 40 | Motor8 |
| 41 | TiltMotorsFront |
| 45 | TiltMotorsRear |
| 46 | TiltMotorRearLeft |
| 47 | TiltMotorRearRight |
| 51 | RCIN1 |
| 52 | RCIN2 |
| 53 | RCIN3 |
| 54 | RCIN4 |
| 55 | RCIN5 |
| 56 | RCIN6 |
| 57 | RCIN7 |
| 58 | RCIN8 |
| 59 | RCIN9 |
| 60 | RCIN10 |
| 61 | RCIN11 |
| 62 | RCIN12 |
| 63 | RCIN13 |
| 64 | RCIN14 |
| 65 | RCIN15 |
| 66 | RCIN16 |
| 67 | Ignition |
| 69 | Starter |
| 70 | Throttle |
| 71 | TrackerYaw |
| 72 | TrackerPitch |
| 73 | ThrottleLeft |
| 74 | ThrottleRight |
| 75 | TiltMotorFrontLeft |
| 76 | TiltMotorFrontRight |
| 77 | ElevonLeft |
| 78 | ElevonRight |
| 79 | VTailLeft |
| 80 | VTailRight |
| 81 | BoostThrottle |
| 82 | Motor9 |
| 83 | Motor10 |
| 84 | Motor11 |
| 85 | Motor12 |
| 86 | DifferentialSpoilerLeft2 |
| 87 | DifferentialSpoilerRight2 |
| 88 | Winch |
| 89 | Main Sail |
| 90 | CameraISO |
| 91 | CameraAperture |
| 92 | CameraFocus |
| 93 | CameraShutterSpeed |
| 94 | Script1 |
| 95 | Script2 |
| 96 | Script3 |
| 97 | Script4 |
| 98 | Script5 |
| 99 | Script6 |
| 100 | Script7 |
| 101 | Script8 |
| 102 | Script9 |
| 103 | Script10 |
| 104 | Script11 |
| 105 | Script12 |
| 106 | Script13 |
| 107 | Script14 |
| 108 | Script15 |
| 109 | Script16 |
| 120 | NeoPixel1 |
| 121 | NeoPixel2 |
| 122 | NeoPixel3 |
| 123 | NeoPixel4 |
| 124 | RateRoll |
| 125 | RatePitch |
| 126 | RateThrust |
| 127 | RateYaw |
| 128 | WingSailElevator |
| 129 | ProfiLED1 |
| 130 | ProfiLED2 |
| 131 | ProfiLED3 |
| 132 | ProfiLEDClock |
| 133 | Winch Clutch |
| 134 | SERVOn_MIN |
| 135 | SERVOn_TRIM |
| 136 | SERVOn_MAX |
| 137 | SailMastRotation |
| 138 | Alarm |
| 139 | Alarm Inverted |
| 140 | RCIN1Scaled |
| 141 | RCIN2Scaled |
| 142 | RCIN3Scaled |
| 143 | RCIN4Scaled |
| 144 | RCIN5Scaled |
| 145 | RCIN6Scaled |
| 146 | RCIN7Scaled |
| 147 | RCIN8Scaled |
| 148 | RCIN9Scaled |
| 149 | RCIN10Scaled |
| 150 | RCIN11Scaled |
| 151 | RCIN12Scaled |
| 152 | RCIN13Scaled |
| 153 | RCIN14Scaled |
| 154 | RCIN15Scaled |
| 155 | RCIN16Scaled |
| 180 | CameraZoom |
minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Trim PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse servo operation. Set to 0 for normal operation. Set to 1 to reverse this output channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
Function assigned to this servo. Setting this to Disabled(0) will setup this output for control by auto missions or MAVLink servo set commands. any other value will enable the corresponding function
| Value | Meaning |
|---|---|
| -1 | GPIO |
| 0 | Disabled |
| 1 | RCPassThru |
| 2 | Flap |
| 3 | FlapAuto |
| 4 | Aileron |
| 6 | Mount1Yaw |
| 7 | Mount1Pitch |
| 8 | Mount1Roll |
| 9 | Mount1Retract |
| 10 | CameraTrigger |
| 12 | Mount2Yaw |
| 13 | Mount2Pitch |
| 14 | Mount2Roll |
| 15 | Mount2Retract |
| 16 | DifferentialSpoilerLeft1 |
| 17 | DifferentialSpoilerRight1 |
| 19 | Elevator |
| 21 | Rudder |
| 22 | SprayerPump |
| 23 | SprayerSpinner |
| 24 | FlaperonLeft |
| 25 | FlaperonRight |
| 26 | GroundSteering |
| 27 | Parachute |
| 28 | Gripper |
| 29 | LandingGear |
| 30 | EngineRunEnable |
| 31 | HeliRSC |
| 32 | HeliTailRSC |
| 33 | Motor1 |
| 34 | Motor2 |
| 35 | Motor3 |
| 36 | Motor4 |
| 37 | Motor5 |
| 38 | Motor6 |
| 39 | Motor7 |
| 40 | Motor8 |
| 41 | TiltMotorsFront |
| 45 | TiltMotorsRear |
| 46 | TiltMotorRearLeft |
| 47 | TiltMotorRearRight |
| 51 | RCIN1 |
| 52 | RCIN2 |
| 53 | RCIN3 |
| 54 | RCIN4 |
| 55 | RCIN5 |
| 56 | RCIN6 |
| 57 | RCIN7 |
| 58 | RCIN8 |
| 59 | RCIN9 |
| 60 | RCIN10 |
| 61 | RCIN11 |
| 62 | RCIN12 |
| 63 | RCIN13 |
| 64 | RCIN14 |
| 65 | RCIN15 |
| 66 | RCIN16 |
| 67 | Ignition |
| 69 | Starter |
| 70 | Throttle |
| 71 | TrackerYaw |
| 72 | TrackerPitch |
| 73 | ThrottleLeft |
| 74 | ThrottleRight |
| 75 | TiltMotorFrontLeft |
| 76 | TiltMotorFrontRight |
| 77 | ElevonLeft |
| 78 | ElevonRight |
| 79 | VTailLeft |
| 80 | VTailRight |
| 81 | BoostThrottle |
| 82 | Motor9 |
| 83 | Motor10 |
| 84 | Motor11 |
| 85 | Motor12 |
| 86 | DifferentialSpoilerLeft2 |
| 87 | DifferentialSpoilerRight2 |
| 88 | Winch |
| 89 | Main Sail |
| 90 | CameraISO |
| 91 | CameraAperture |
| 92 | CameraFocus |
| 93 | CameraShutterSpeed |
| 94 | Script1 |
| 95 | Script2 |
| 96 | Script3 |
| 97 | Script4 |
| 98 | Script5 |
| 99 | Script6 |
| 100 | Script7 |
| 101 | Script8 |
| 102 | Script9 |
| 103 | Script10 |
| 104 | Script11 |
| 105 | Script12 |
| 106 | Script13 |
| 107 | Script14 |
| 108 | Script15 |
| 109 | Script16 |
| 120 | NeoPixel1 |
| 121 | NeoPixel2 |
| 122 | NeoPixel3 |
| 123 | NeoPixel4 |
| 124 | RateRoll |
| 125 | RatePitch |
| 126 | RateThrust |
| 127 | RateYaw |
| 128 | WingSailElevator |
| 129 | ProfiLED1 |
| 130 | ProfiLED2 |
| 131 | ProfiLED3 |
| 132 | ProfiLEDClock |
| 133 | Winch Clutch |
| 134 | SERVOn_MIN |
| 135 | SERVOn_TRIM |
| 136 | SERVOn_MAX |
| 137 | SailMastRotation |
| 138 | Alarm |
| 139 | Alarm Inverted |
| 140 | RCIN1Scaled |
| 141 | RCIN2Scaled |
| 142 | RCIN3Scaled |
| 143 | RCIN4Scaled |
| 144 | RCIN5Scaled |
| 145 | RCIN6Scaled |
| 146 | RCIN7Scaled |
| 147 | RCIN8Scaled |
| 148 | RCIN9Scaled |
| 149 | RCIN10Scaled |
| 150 | RCIN11Scaled |
| 151 | RCIN12Scaled |
| 152 | RCIN13Scaled |
| 153 | RCIN14Scaled |
| 154 | RCIN15Scaled |
| 155 | RCIN16Scaled |
| 180 | CameraZoom |
minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Trim PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse servo operation. Set to 0 for normal operation. Set to 1 to reverse this output channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
Function assigned to this servo. Setting this to Disabled(0) will setup this output for control by auto missions or MAVLink servo set commands. any other value will enable the corresponding function
| Value | Meaning |
|---|---|
| -1 | GPIO |
| 0 | Disabled |
| 1 | RCPassThru |
| 2 | Flap |
| 3 | FlapAuto |
| 4 | Aileron |
| 6 | Mount1Yaw |
| 7 | Mount1Pitch |
| 8 | Mount1Roll |
| 9 | Mount1Retract |
| 10 | CameraTrigger |
| 12 | Mount2Yaw |
| 13 | Mount2Pitch |
| 14 | Mount2Roll |
| 15 | Mount2Retract |
| 16 | DifferentialSpoilerLeft1 |
| 17 | DifferentialSpoilerRight1 |
| 19 | Elevator |
| 21 | Rudder |
| 22 | SprayerPump |
| 23 | SprayerSpinner |
| 24 | FlaperonLeft |
| 25 | FlaperonRight |
| 26 | GroundSteering |
| 27 | Parachute |
| 28 | Gripper |
| 29 | LandingGear |
| 30 | EngineRunEnable |
| 31 | HeliRSC |
| 32 | HeliTailRSC |
| 33 | Motor1 |
| 34 | Motor2 |
| 35 | Motor3 |
| 36 | Motor4 |
| 37 | Motor5 |
| 38 | Motor6 |
| 39 | Motor7 |
| 40 | Motor8 |
| 41 | TiltMotorsFront |
| 45 | TiltMotorsRear |
| 46 | TiltMotorRearLeft |
| 47 | TiltMotorRearRight |
| 51 | RCIN1 |
| 52 | RCIN2 |
| 53 | RCIN3 |
| 54 | RCIN4 |
| 55 | RCIN5 |
| 56 | RCIN6 |
| 57 | RCIN7 |
| 58 | RCIN8 |
| 59 | RCIN9 |
| 60 | RCIN10 |
| 61 | RCIN11 |
| 62 | RCIN12 |
| 63 | RCIN13 |
| 64 | RCIN14 |
| 65 | RCIN15 |
| 66 | RCIN16 |
| 67 | Ignition |
| 69 | Starter |
| 70 | Throttle |
| 71 | TrackerYaw |
| 72 | TrackerPitch |
| 73 | ThrottleLeft |
| 74 | ThrottleRight |
| 75 | TiltMotorFrontLeft |
| 76 | TiltMotorFrontRight |
| 77 | ElevonLeft |
| 78 | ElevonRight |
| 79 | VTailLeft |
| 80 | VTailRight |
| 81 | BoostThrottle |
| 82 | Motor9 |
| 83 | Motor10 |
| 84 | Motor11 |
| 85 | Motor12 |
| 86 | DifferentialSpoilerLeft2 |
| 87 | DifferentialSpoilerRight2 |
| 88 | Winch |
| 89 | Main Sail |
| 90 | CameraISO |
| 91 | CameraAperture |
| 92 | CameraFocus |
| 93 | CameraShutterSpeed |
| 94 | Script1 |
| 95 | Script2 |
| 96 | Script3 |
| 97 | Script4 |
| 98 | Script5 |
| 99 | Script6 |
| 100 | Script7 |
| 101 | Script8 |
| 102 | Script9 |
| 103 | Script10 |
| 104 | Script11 |
| 105 | Script12 |
| 106 | Script13 |
| 107 | Script14 |
| 108 | Script15 |
| 109 | Script16 |
| 120 | NeoPixel1 |
| 121 | NeoPixel2 |
| 122 | NeoPixel3 |
| 123 | NeoPixel4 |
| 124 | RateRoll |
| 125 | RatePitch |
| 126 | RateThrust |
| 127 | RateYaw |
| 128 | WingSailElevator |
| 129 | ProfiLED1 |
| 130 | ProfiLED2 |
| 131 | ProfiLED3 |
| 132 | ProfiLEDClock |
| 133 | Winch Clutch |
| 134 | SERVOn_MIN |
| 135 | SERVOn_TRIM |
| 136 | SERVOn_MAX |
| 137 | SailMastRotation |
| 138 | Alarm |
| 139 | Alarm Inverted |
| 140 | RCIN1Scaled |
| 141 | RCIN2Scaled |
| 142 | RCIN3Scaled |
| 143 | RCIN4Scaled |
| 144 | RCIN5Scaled |
| 145 | RCIN6Scaled |
| 146 | RCIN7Scaled |
| 147 | RCIN8Scaled |
| 148 | RCIN9Scaled |
| 149 | RCIN10Scaled |
| 150 | RCIN11Scaled |
| 151 | RCIN12Scaled |
| 152 | RCIN13Scaled |
| 153 | RCIN14Scaled |
| 154 | RCIN15Scaled |
| 155 | RCIN16Scaled |
| 180 | CameraZoom |
minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Trim PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse servo operation. Set to 0 for normal operation. Set to 1 to reverse this output channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
Function assigned to this servo. Setting this to Disabled(0) will setup this output for control by auto missions or MAVLink servo set commands. any other value will enable the corresponding function
| Value | Meaning |
|---|---|
| -1 | GPIO |
| 0 | Disabled |
| 1 | RCPassThru |
| 2 | Flap |
| 3 | FlapAuto |
| 4 | Aileron |
| 6 | Mount1Yaw |
| 7 | Mount1Pitch |
| 8 | Mount1Roll |
| 9 | Mount1Retract |
| 10 | CameraTrigger |
| 12 | Mount2Yaw |
| 13 | Mount2Pitch |
| 14 | Mount2Roll |
| 15 | Mount2Retract |
| 16 | DifferentialSpoilerLeft1 |
| 17 | DifferentialSpoilerRight1 |
| 19 | Elevator |
| 21 | Rudder |
| 22 | SprayerPump |
| 23 | SprayerSpinner |
| 24 | FlaperonLeft |
| 25 | FlaperonRight |
| 26 | GroundSteering |
| 27 | Parachute |
| 28 | Gripper |
| 29 | LandingGear |
| 30 | EngineRunEnable |
| 31 | HeliRSC |
| 32 | HeliTailRSC |
| 33 | Motor1 |
| 34 | Motor2 |
| 35 | Motor3 |
| 36 | Motor4 |
| 37 | Motor5 |
| 38 | Motor6 |
| 39 | Motor7 |
| 40 | Motor8 |
| 41 | TiltMotorsFront |
| 45 | TiltMotorsRear |
| 46 | TiltMotorRearLeft |
| 47 | TiltMotorRearRight |
| 51 | RCIN1 |
| 52 | RCIN2 |
| 53 | RCIN3 |
| 54 | RCIN4 |
| 55 | RCIN5 |
| 56 | RCIN6 |
| 57 | RCIN7 |
| 58 | RCIN8 |
| 59 | RCIN9 |
| 60 | RCIN10 |
| 61 | RCIN11 |
| 62 | RCIN12 |
| 63 | RCIN13 |
| 64 | RCIN14 |
| 65 | RCIN15 |
| 66 | RCIN16 |
| 67 | Ignition |
| 69 | Starter |
| 70 | Throttle |
| 71 | TrackerYaw |
| 72 | TrackerPitch |
| 73 | ThrottleLeft |
| 74 | ThrottleRight |
| 75 | TiltMotorFrontLeft |
| 76 | TiltMotorFrontRight |
| 77 | ElevonLeft |
| 78 | ElevonRight |
| 79 | VTailLeft |
| 80 | VTailRight |
| 81 | BoostThrottle |
| 82 | Motor9 |
| 83 | Motor10 |
| 84 | Motor11 |
| 85 | Motor12 |
| 86 | DifferentialSpoilerLeft2 |
| 87 | DifferentialSpoilerRight2 |
| 88 | Winch |
| 89 | Main Sail |
| 90 | CameraISO |
| 91 | CameraAperture |
| 92 | CameraFocus |
| 93 | CameraShutterSpeed |
| 94 | Script1 |
| 95 | Script2 |
| 96 | Script3 |
| 97 | Script4 |
| 98 | Script5 |
| 99 | Script6 |
| 100 | Script7 |
| 101 | Script8 |
| 102 | Script9 |
| 103 | Script10 |
| 104 | Script11 |
| 105 | Script12 |
| 106 | Script13 |
| 107 | Script14 |
| 108 | Script15 |
| 109 | Script16 |
| 120 | NeoPixel1 |
| 121 | NeoPixel2 |
| 122 | NeoPixel3 |
| 123 | NeoPixel4 |
| 124 | RateRoll |
| 125 | RatePitch |
| 126 | RateThrust |
| 127 | RateYaw |
| 128 | WingSailElevator |
| 129 | ProfiLED1 |
| 130 | ProfiLED2 |
| 131 | ProfiLED3 |
| 132 | ProfiLEDClock |
| 133 | Winch Clutch |
| 134 | SERVOn_MIN |
| 135 | SERVOn_TRIM |
| 136 | SERVOn_MAX |
| 137 | SailMastRotation |
| 138 | Alarm |
| 139 | Alarm Inverted |
| 140 | RCIN1Scaled |
| 141 | RCIN2Scaled |
| 142 | RCIN3Scaled |
| 143 | RCIN4Scaled |
| 144 | RCIN5Scaled |
| 145 | RCIN6Scaled |
| 146 | RCIN7Scaled |
| 147 | RCIN8Scaled |
| 148 | RCIN9Scaled |
| 149 | RCIN10Scaled |
| 150 | RCIN11Scaled |
| 151 | RCIN12Scaled |
| 152 | RCIN13Scaled |
| 153 | RCIN14Scaled |
| 154 | RCIN15Scaled |
| 155 | RCIN16Scaled |
| 180 | CameraZoom |
minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Trim PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse servo operation. Set to 0 for normal operation. Set to 1 to reverse this output channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
Function assigned to this servo. Setting this to Disabled(0) will setup this output for control by auto missions or MAVLink servo set commands. any other value will enable the corresponding function
| Value | Meaning |
|---|---|
| -1 | GPIO |
| 0 | Disabled |
| 1 | RCPassThru |
| 2 | Flap |
| 3 | FlapAuto |
| 4 | Aileron |
| 6 | Mount1Yaw |
| 7 | Mount1Pitch |
| 8 | Mount1Roll |
| 9 | Mount1Retract |
| 10 | CameraTrigger |
| 12 | Mount2Yaw |
| 13 | Mount2Pitch |
| 14 | Mount2Roll |
| 15 | Mount2Retract |
| 16 | DifferentialSpoilerLeft1 |
| 17 | DifferentialSpoilerRight1 |
| 19 | Elevator |
| 21 | Rudder |
| 22 | SprayerPump |
| 23 | SprayerSpinner |
| 24 | FlaperonLeft |
| 25 | FlaperonRight |
| 26 | GroundSteering |
| 27 | Parachute |
| 28 | Gripper |
| 29 | LandingGear |
| 30 | EngineRunEnable |
| 31 | HeliRSC |
| 32 | HeliTailRSC |
| 33 | Motor1 |
| 34 | Motor2 |
| 35 | Motor3 |
| 36 | Motor4 |
| 37 | Motor5 |
| 38 | Motor6 |
| 39 | Motor7 |
| 40 | Motor8 |
| 41 | TiltMotorsFront |
| 45 | TiltMotorsRear |
| 46 | TiltMotorRearLeft |
| 47 | TiltMotorRearRight |
| 51 | RCIN1 |
| 52 | RCIN2 |
| 53 | RCIN3 |
| 54 | RCIN4 |
| 55 | RCIN5 |
| 56 | RCIN6 |
| 57 | RCIN7 |
| 58 | RCIN8 |
| 59 | RCIN9 |
| 60 | RCIN10 |
| 61 | RCIN11 |
| 62 | RCIN12 |
| 63 | RCIN13 |
| 64 | RCIN14 |
| 65 | RCIN15 |
| 66 | RCIN16 |
| 67 | Ignition |
| 69 | Starter |
| 70 | Throttle |
| 71 | TrackerYaw |
| 72 | TrackerPitch |
| 73 | ThrottleLeft |
| 74 | ThrottleRight |
| 75 | TiltMotorFrontLeft |
| 76 | TiltMotorFrontRight |
| 77 | ElevonLeft |
| 78 | ElevonRight |
| 79 | VTailLeft |
| 80 | VTailRight |
| 81 | BoostThrottle |
| 82 | Motor9 |
| 83 | Motor10 |
| 84 | Motor11 |
| 85 | Motor12 |
| 86 | DifferentialSpoilerLeft2 |
| 87 | DifferentialSpoilerRight2 |
| 88 | Winch |
| 89 | Main Sail |
| 90 | CameraISO |
| 91 | CameraAperture |
| 92 | CameraFocus |
| 93 | CameraShutterSpeed |
| 94 | Script1 |
| 95 | Script2 |
| 96 | Script3 |
| 97 | Script4 |
| 98 | Script5 |
| 99 | Script6 |
| 100 | Script7 |
| 101 | Script8 |
| 102 | Script9 |
| 103 | Script10 |
| 104 | Script11 |
| 105 | Script12 |
| 106 | Script13 |
| 107 | Script14 |
| 108 | Script15 |
| 109 | Script16 |
| 120 | NeoPixel1 |
| 121 | NeoPixel2 |
| 122 | NeoPixel3 |
| 123 | NeoPixel4 |
| 124 | RateRoll |
| 125 | RatePitch |
| 126 | RateThrust |
| 127 | RateYaw |
| 128 | WingSailElevator |
| 129 | ProfiLED1 |
| 130 | ProfiLED2 |
| 131 | ProfiLED3 |
| 132 | ProfiLEDClock |
| 133 | Winch Clutch |
| 134 | SERVOn_MIN |
| 135 | SERVOn_TRIM |
| 136 | SERVOn_MAX |
| 137 | SailMastRotation |
| 138 | Alarm |
| 139 | Alarm Inverted |
| 140 | RCIN1Scaled |
| 141 | RCIN2Scaled |
| 142 | RCIN3Scaled |
| 143 | RCIN4Scaled |
| 144 | RCIN5Scaled |
| 145 | RCIN6Scaled |
| 146 | RCIN7Scaled |
| 147 | RCIN8Scaled |
| 148 | RCIN9Scaled |
| 149 | RCIN10Scaled |
| 150 | RCIN11Scaled |
| 151 | RCIN12Scaled |
| 152 | RCIN13Scaled |
| 153 | RCIN14Scaled |
| 154 | RCIN15Scaled |
| 155 | RCIN16Scaled |
| 180 | CameraZoom |
minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Trim PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse servo operation. Set to 0 for normal operation. Set to 1 to reverse this output channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
Function assigned to this servo. Setting this to Disabled(0) will setup this output for control by auto missions or MAVLink servo set commands. any other value will enable the corresponding function
| Value | Meaning |
|---|---|
| -1 | GPIO |
| 0 | Disabled |
| 1 | RCPassThru |
| 2 | Flap |
| 3 | FlapAuto |
| 4 | Aileron |
| 6 | Mount1Yaw |
| 7 | Mount1Pitch |
| 8 | Mount1Roll |
| 9 | Mount1Retract |
| 10 | CameraTrigger |
| 12 | Mount2Yaw |
| 13 | Mount2Pitch |
| 14 | Mount2Roll |
| 15 | Mount2Retract |
| 16 | DifferentialSpoilerLeft1 |
| 17 | DifferentialSpoilerRight1 |
| 19 | Elevator |
| 21 | Rudder |
| 22 | SprayerPump |
| 23 | SprayerSpinner |
| 24 | FlaperonLeft |
| 25 | FlaperonRight |
| 26 | GroundSteering |
| 27 | Parachute |
| 28 | Gripper |
| 29 | LandingGear |
| 30 | EngineRunEnable |
| 31 | HeliRSC |
| 32 | HeliTailRSC |
| 33 | Motor1 |
| 34 | Motor2 |
| 35 | Motor3 |
| 36 | Motor4 |
| 37 | Motor5 |
| 38 | Motor6 |
| 39 | Motor7 |
| 40 | Motor8 |
| 41 | TiltMotorsFront |
| 45 | TiltMotorsRear |
| 46 | TiltMotorRearLeft |
| 47 | TiltMotorRearRight |
| 51 | RCIN1 |
| 52 | RCIN2 |
| 53 | RCIN3 |
| 54 | RCIN4 |
| 55 | RCIN5 |
| 56 | RCIN6 |
| 57 | RCIN7 |
| 58 | RCIN8 |
| 59 | RCIN9 |
| 60 | RCIN10 |
| 61 | RCIN11 |
| 62 | RCIN12 |
| 63 | RCIN13 |
| 64 | RCIN14 |
| 65 | RCIN15 |
| 66 | RCIN16 |
| 67 | Ignition |
| 69 | Starter |
| 70 | Throttle |
| 71 | TrackerYaw |
| 72 | TrackerPitch |
| 73 | ThrottleLeft |
| 74 | ThrottleRight |
| 75 | TiltMotorFrontLeft |
| 76 | TiltMotorFrontRight |
| 77 | ElevonLeft |
| 78 | ElevonRight |
| 79 | VTailLeft |
| 80 | VTailRight |
| 81 | BoostThrottle |
| 82 | Motor9 |
| 83 | Motor10 |
| 84 | Motor11 |
| 85 | Motor12 |
| 86 | DifferentialSpoilerLeft2 |
| 87 | DifferentialSpoilerRight2 |
| 88 | Winch |
| 89 | Main Sail |
| 90 | CameraISO |
| 91 | CameraAperture |
| 92 | CameraFocus |
| 93 | CameraShutterSpeed |
| 94 | Script1 |
| 95 | Script2 |
| 96 | Script3 |
| 97 | Script4 |
| 98 | Script5 |
| 99 | Script6 |
| 100 | Script7 |
| 101 | Script8 |
| 102 | Script9 |
| 103 | Script10 |
| 104 | Script11 |
| 105 | Script12 |
| 106 | Script13 |
| 107 | Script14 |
| 108 | Script15 |
| 109 | Script16 |
| 120 | NeoPixel1 |
| 121 | NeoPixel2 |
| 122 | NeoPixel3 |
| 123 | NeoPixel4 |
| 124 | RateRoll |
| 125 | RatePitch |
| 126 | RateThrust |
| 127 | RateYaw |
| 128 | WingSailElevator |
| 129 | ProfiLED1 |
| 130 | ProfiLED2 |
| 131 | ProfiLED3 |
| 132 | ProfiLEDClock |
| 133 | Winch Clutch |
| 134 | SERVOn_MIN |
| 135 | SERVOn_TRIM |
| 136 | SERVOn_MAX |
| 137 | SailMastRotation |
| 138 | Alarm |
| 139 | Alarm Inverted |
| 140 | RCIN1Scaled |
| 141 | RCIN2Scaled |
| 142 | RCIN3Scaled |
| 143 | RCIN4Scaled |
| 144 | RCIN5Scaled |
| 145 | RCIN6Scaled |
| 146 | RCIN7Scaled |
| 147 | RCIN8Scaled |
| 148 | RCIN9Scaled |
| 149 | RCIN10Scaled |
| 150 | RCIN11Scaled |
| 151 | RCIN12Scaled |
| 152 | RCIN13Scaled |
| 153 | RCIN14Scaled |
| 154 | RCIN15Scaled |
| 155 | RCIN16Scaled |
| 180 | CameraZoom |
minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Trim PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse servo operation. Set to 0 for normal operation. Set to 1 to reverse this output channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
Function assigned to this servo. Setting this to Disabled(0) will setup this output for control by auto missions or MAVLink servo set commands. any other value will enable the corresponding function
| Value | Meaning |
|---|---|
| -1 | GPIO |
| 0 | Disabled |
| 1 | RCPassThru |
| 2 | Flap |
| 3 | FlapAuto |
| 4 | Aileron |
| 6 | Mount1Yaw |
| 7 | Mount1Pitch |
| 8 | Mount1Roll |
| 9 | Mount1Retract |
| 10 | CameraTrigger |
| 12 | Mount2Yaw |
| 13 | Mount2Pitch |
| 14 | Mount2Roll |
| 15 | Mount2Retract |
| 16 | DifferentialSpoilerLeft1 |
| 17 | DifferentialSpoilerRight1 |
| 19 | Elevator |
| 21 | Rudder |
| 22 | SprayerPump |
| 23 | SprayerSpinner |
| 24 | FlaperonLeft |
| 25 | FlaperonRight |
| 26 | GroundSteering |
| 27 | Parachute |
| 28 | Gripper |
| 29 | LandingGear |
| 30 | EngineRunEnable |
| 31 | HeliRSC |
| 32 | HeliTailRSC |
| 33 | Motor1 |
| 34 | Motor2 |
| 35 | Motor3 |
| 36 | Motor4 |
| 37 | Motor5 |
| 38 | Motor6 |
| 39 | Motor7 |
| 40 | Motor8 |
| 41 | TiltMotorsFront |
| 45 | TiltMotorsRear |
| 46 | TiltMotorRearLeft |
| 47 | TiltMotorRearRight |
| 51 | RCIN1 |
| 52 | RCIN2 |
| 53 | RCIN3 |
| 54 | RCIN4 |
| 55 | RCIN5 |
| 56 | RCIN6 |
| 57 | RCIN7 |
| 58 | RCIN8 |
| 59 | RCIN9 |
| 60 | RCIN10 |
| 61 | RCIN11 |
| 62 | RCIN12 |
| 63 | RCIN13 |
| 64 | RCIN14 |
| 65 | RCIN15 |
| 66 | RCIN16 |
| 67 | Ignition |
| 69 | Starter |
| 70 | Throttle |
| 71 | TrackerYaw |
| 72 | TrackerPitch |
| 73 | ThrottleLeft |
| 74 | ThrottleRight |
| 75 | TiltMotorFrontLeft |
| 76 | TiltMotorFrontRight |
| 77 | ElevonLeft |
| 78 | ElevonRight |
| 79 | VTailLeft |
| 80 | VTailRight |
| 81 | BoostThrottle |
| 82 | Motor9 |
| 83 | Motor10 |
| 84 | Motor11 |
| 85 | Motor12 |
| 86 | DifferentialSpoilerLeft2 |
| 87 | DifferentialSpoilerRight2 |
| 88 | Winch |
| 89 | Main Sail |
| 90 | CameraISO |
| 91 | CameraAperture |
| 92 | CameraFocus |
| 93 | CameraShutterSpeed |
| 94 | Script1 |
| 95 | Script2 |
| 96 | Script3 |
| 97 | Script4 |
| 98 | Script5 |
| 99 | Script6 |
| 100 | Script7 |
| 101 | Script8 |
| 102 | Script9 |
| 103 | Script10 |
| 104 | Script11 |
| 105 | Script12 |
| 106 | Script13 |
| 107 | Script14 |
| 108 | Script15 |
| 109 | Script16 |
| 120 | NeoPixel1 |
| 121 | NeoPixel2 |
| 122 | NeoPixel3 |
| 123 | NeoPixel4 |
| 124 | RateRoll |
| 125 | RatePitch |
| 126 | RateThrust |
| 127 | RateYaw |
| 128 | WingSailElevator |
| 129 | ProfiLED1 |
| 130 | ProfiLED2 |
| 131 | ProfiLED3 |
| 132 | ProfiLEDClock |
| 133 | Winch Clutch |
| 134 | SERVOn_MIN |
| 135 | SERVOn_TRIM |
| 136 | SERVOn_MAX |
| 137 | SailMastRotation |
| 138 | Alarm |
| 139 | Alarm Inverted |
| 140 | RCIN1Scaled |
| 141 | RCIN2Scaled |
| 142 | RCIN3Scaled |
| 143 | RCIN4Scaled |
| 144 | RCIN5Scaled |
| 145 | RCIN6Scaled |
| 146 | RCIN7Scaled |
| 147 | RCIN8Scaled |
| 148 | RCIN9Scaled |
| 149 | RCIN10Scaled |
| 150 | RCIN11Scaled |
| 151 | RCIN12Scaled |
| 152 | RCIN13Scaled |
| 153 | RCIN14Scaled |
| 154 | RCIN15Scaled |
| 155 | RCIN16Scaled |
| 180 | CameraZoom |
minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Trim PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse servo operation. Set to 0 for normal operation. Set to 1 to reverse this output channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
Function assigned to this servo. Setting this to Disabled(0) will setup this output for control by auto missions or MAVLink servo set commands. any other value will enable the corresponding function
| Value | Meaning |
|---|---|
| -1 | GPIO |
| 0 | Disabled |
| 1 | RCPassThru |
| 2 | Flap |
| 3 | FlapAuto |
| 4 | Aileron |
| 6 | Mount1Yaw |
| 7 | Mount1Pitch |
| 8 | Mount1Roll |
| 9 | Mount1Retract |
| 10 | CameraTrigger |
| 12 | Mount2Yaw |
| 13 | Mount2Pitch |
| 14 | Mount2Roll |
| 15 | Mount2Retract |
| 16 | DifferentialSpoilerLeft1 |
| 17 | DifferentialSpoilerRight1 |
| 19 | Elevator |
| 21 | Rudder |
| 22 | SprayerPump |
| 23 | SprayerSpinner |
| 24 | FlaperonLeft |
| 25 | FlaperonRight |
| 26 | GroundSteering |
| 27 | Parachute |
| 28 | Gripper |
| 29 | LandingGear |
| 30 | EngineRunEnable |
| 31 | HeliRSC |
| 32 | HeliTailRSC |
| 33 | Motor1 |
| 34 | Motor2 |
| 35 | Motor3 |
| 36 | Motor4 |
| 37 | Motor5 |
| 38 | Motor6 |
| 39 | Motor7 |
| 40 | Motor8 |
| 41 | TiltMotorsFront |
| 45 | TiltMotorsRear |
| 46 | TiltMotorRearLeft |
| 47 | TiltMotorRearRight |
| 51 | RCIN1 |
| 52 | RCIN2 |
| 53 | RCIN3 |
| 54 | RCIN4 |
| 55 | RCIN5 |
| 56 | RCIN6 |
| 57 | RCIN7 |
| 58 | RCIN8 |
| 59 | RCIN9 |
| 60 | RCIN10 |
| 61 | RCIN11 |
| 62 | RCIN12 |
| 63 | RCIN13 |
| 64 | RCIN14 |
| 65 | RCIN15 |
| 66 | RCIN16 |
| 67 | Ignition |
| 69 | Starter |
| 70 | Throttle |
| 71 | TrackerYaw |
| 72 | TrackerPitch |
| 73 | ThrottleLeft |
| 74 | ThrottleRight |
| 75 | TiltMotorFrontLeft |
| 76 | TiltMotorFrontRight |
| 77 | ElevonLeft |
| 78 | ElevonRight |
| 79 | VTailLeft |
| 80 | VTailRight |
| 81 | BoostThrottle |
| 82 | Motor9 |
| 83 | Motor10 |
| 84 | Motor11 |
| 85 | Motor12 |
| 86 | DifferentialSpoilerLeft2 |
| 87 | DifferentialSpoilerRight2 |
| 88 | Winch |
| 89 | Main Sail |
| 90 | CameraISO |
| 91 | CameraAperture |
| 92 | CameraFocus |
| 93 | CameraShutterSpeed |
| 94 | Script1 |
| 95 | Script2 |
| 96 | Script3 |
| 97 | Script4 |
| 98 | Script5 |
| 99 | Script6 |
| 100 | Script7 |
| 101 | Script8 |
| 102 | Script9 |
| 103 | Script10 |
| 104 | Script11 |
| 105 | Script12 |
| 106 | Script13 |
| 107 | Script14 |
| 108 | Script15 |
| 109 | Script16 |
| 120 | NeoPixel1 |
| 121 | NeoPixel2 |
| 122 | NeoPixel3 |
| 123 | NeoPixel4 |
| 124 | RateRoll |
| 125 | RatePitch |
| 126 | RateThrust |
| 127 | RateYaw |
| 128 | WingSailElevator |
| 129 | ProfiLED1 |
| 130 | ProfiLED2 |
| 131 | ProfiLED3 |
| 132 | ProfiLEDClock |
| 133 | Winch Clutch |
| 134 | SERVOn_MIN |
| 135 | SERVOn_TRIM |
| 136 | SERVOn_MAX |
| 137 | SailMastRotation |
| 138 | Alarm |
| 139 | Alarm Inverted |
| 140 | RCIN1Scaled |
| 141 | RCIN2Scaled |
| 142 | RCIN3Scaled |
| 143 | RCIN4Scaled |
| 144 | RCIN5Scaled |
| 145 | RCIN6Scaled |
| 146 | RCIN7Scaled |
| 147 | RCIN8Scaled |
| 148 | RCIN9Scaled |
| 149 | RCIN10Scaled |
| 150 | RCIN11Scaled |
| 151 | RCIN12Scaled |
| 152 | RCIN13Scaled |
| 153 | RCIN14Scaled |
| 154 | RCIN15Scaled |
| 155 | RCIN16Scaled |
| 180 | CameraZoom |
minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Trim PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse servo operation. Set to 0 for normal operation. Set to 1 to reverse this output channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
Function assigned to this servo. Setting this to Disabled(0) will setup this output for control by auto missions or MAVLink servo set commands. any other value will enable the corresponding function
| Value | Meaning |
|---|---|
| -1 | GPIO |
| 0 | Disabled |
| 1 | RCPassThru |
| 2 | Flap |
| 3 | FlapAuto |
| 4 | Aileron |
| 6 | Mount1Yaw |
| 7 | Mount1Pitch |
| 8 | Mount1Roll |
| 9 | Mount1Retract |
| 10 | CameraTrigger |
| 12 | Mount2Yaw |
| 13 | Mount2Pitch |
| 14 | Mount2Roll |
| 15 | Mount2Retract |
| 16 | DifferentialSpoilerLeft1 |
| 17 | DifferentialSpoilerRight1 |
| 19 | Elevator |
| 21 | Rudder |
| 22 | SprayerPump |
| 23 | SprayerSpinner |
| 24 | FlaperonLeft |
| 25 | FlaperonRight |
| 26 | GroundSteering |
| 27 | Parachute |
| 28 | Gripper |
| 29 | LandingGear |
| 30 | EngineRunEnable |
| 31 | HeliRSC |
| 32 | HeliTailRSC |
| 33 | Motor1 |
| 34 | Motor2 |
| 35 | Motor3 |
| 36 | Motor4 |
| 37 | Motor5 |
| 38 | Motor6 |
| 39 | Motor7 |
| 40 | Motor8 |
| 41 | TiltMotorsFront |
| 45 | TiltMotorsRear |
| 46 | TiltMotorRearLeft |
| 47 | TiltMotorRearRight |
| 51 | RCIN1 |
| 52 | RCIN2 |
| 53 | RCIN3 |
| 54 | RCIN4 |
| 55 | RCIN5 |
| 56 | RCIN6 |
| 57 | RCIN7 |
| 58 | RCIN8 |
| 59 | RCIN9 |
| 60 | RCIN10 |
| 61 | RCIN11 |
| 62 | RCIN12 |
| 63 | RCIN13 |
| 64 | RCIN14 |
| 65 | RCIN15 |
| 66 | RCIN16 |
| 67 | Ignition |
| 69 | Starter |
| 70 | Throttle |
| 71 | TrackerYaw |
| 72 | TrackerPitch |
| 73 | ThrottleLeft |
| 74 | ThrottleRight |
| 75 | TiltMotorFrontLeft |
| 76 | TiltMotorFrontRight |
| 77 | ElevonLeft |
| 78 | ElevonRight |
| 79 | VTailLeft |
| 80 | VTailRight |
| 81 | BoostThrottle |
| 82 | Motor9 |
| 83 | Motor10 |
| 84 | Motor11 |
| 85 | Motor12 |
| 86 | DifferentialSpoilerLeft2 |
| 87 | DifferentialSpoilerRight2 |
| 88 | Winch |
| 89 | Main Sail |
| 90 | CameraISO |
| 91 | CameraAperture |
| 92 | CameraFocus |
| 93 | CameraShutterSpeed |
| 94 | Script1 |
| 95 | Script2 |
| 96 | Script3 |
| 97 | Script4 |
| 98 | Script5 |
| 99 | Script6 |
| 100 | Script7 |
| 101 | Script8 |
| 102 | Script9 |
| 103 | Script10 |
| 104 | Script11 |
| 105 | Script12 |
| 106 | Script13 |
| 107 | Script14 |
| 108 | Script15 |
| 109 | Script16 |
| 120 | NeoPixel1 |
| 121 | NeoPixel2 |
| 122 | NeoPixel3 |
| 123 | NeoPixel4 |
| 124 | RateRoll |
| 125 | RatePitch |
| 126 | RateThrust |
| 127 | RateYaw |
| 128 | WingSailElevator |
| 129 | ProfiLED1 |
| 130 | ProfiLED2 |
| 131 | ProfiLED3 |
| 132 | ProfiLEDClock |
| 133 | Winch Clutch |
| 134 | SERVOn_MIN |
| 135 | SERVOn_TRIM |
| 136 | SERVOn_MAX |
| 137 | SailMastRotation |
| 138 | Alarm |
| 139 | Alarm Inverted |
| 140 | RCIN1Scaled |
| 141 | RCIN2Scaled |
| 142 | RCIN3Scaled |
| 143 | RCIN4Scaled |
| 144 | RCIN5Scaled |
| 145 | RCIN6Scaled |
| 146 | RCIN7Scaled |
| 147 | RCIN8Scaled |
| 148 | RCIN9Scaled |
| 149 | RCIN10Scaled |
| 150 | RCIN11Scaled |
| 151 | RCIN12Scaled |
| 152 | RCIN13Scaled |
| 153 | RCIN14Scaled |
| 154 | RCIN15Scaled |
| 155 | RCIN16Scaled |
| 180 | CameraZoom |
minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Trim PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse servo operation. Set to 0 for normal operation. Set to 1 to reverse this output channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
Function assigned to this servo. Setting this to Disabled(0) will setup this output for control by auto missions or MAVLink servo set commands. any other value will enable the corresponding function
| Value | Meaning |
|---|---|
| -1 | GPIO |
| 0 | Disabled |
| 1 | RCPassThru |
| 2 | Flap |
| 3 | FlapAuto |
| 4 | Aileron |
| 6 | Mount1Yaw |
| 7 | Mount1Pitch |
| 8 | Mount1Roll |
| 9 | Mount1Retract |
| 10 | CameraTrigger |
| 12 | Mount2Yaw |
| 13 | Mount2Pitch |
| 14 | Mount2Roll |
| 15 | Mount2Retract |
| 16 | DifferentialSpoilerLeft1 |
| 17 | DifferentialSpoilerRight1 |
| 19 | Elevator |
| 21 | Rudder |
| 22 | SprayerPump |
| 23 | SprayerSpinner |
| 24 | FlaperonLeft |
| 25 | FlaperonRight |
| 26 | GroundSteering |
| 27 | Parachute |
| 28 | Gripper |
| 29 | LandingGear |
| 30 | EngineRunEnable |
| 31 | HeliRSC |
| 32 | HeliTailRSC |
| 33 | Motor1 |
| 34 | Motor2 |
| 35 | Motor3 |
| 36 | Motor4 |
| 37 | Motor5 |
| 38 | Motor6 |
| 39 | Motor7 |
| 40 | Motor8 |
| 41 | TiltMotorsFront |
| 45 | TiltMotorsRear |
| 46 | TiltMotorRearLeft |
| 47 | TiltMotorRearRight |
| 51 | RCIN1 |
| 52 | RCIN2 |
| 53 | RCIN3 |
| 54 | RCIN4 |
| 55 | RCIN5 |
| 56 | RCIN6 |
| 57 | RCIN7 |
| 58 | RCIN8 |
| 59 | RCIN9 |
| 60 | RCIN10 |
| 61 | RCIN11 |
| 62 | RCIN12 |
| 63 | RCIN13 |
| 64 | RCIN14 |
| 65 | RCIN15 |
| 66 | RCIN16 |
| 67 | Ignition |
| 69 | Starter |
| 70 | Throttle |
| 71 | TrackerYaw |
| 72 | TrackerPitch |
| 73 | ThrottleLeft |
| 74 | ThrottleRight |
| 75 | TiltMotorFrontLeft |
| 76 | TiltMotorFrontRight |
| 77 | ElevonLeft |
| 78 | ElevonRight |
| 79 | VTailLeft |
| 80 | VTailRight |
| 81 | BoostThrottle |
| 82 | Motor9 |
| 83 | Motor10 |
| 84 | Motor11 |
| 85 | Motor12 |
| 86 | DifferentialSpoilerLeft2 |
| 87 | DifferentialSpoilerRight2 |
| 88 | Winch |
| 89 | Main Sail |
| 90 | CameraISO |
| 91 | CameraAperture |
| 92 | CameraFocus |
| 93 | CameraShutterSpeed |
| 94 | Script1 |
| 95 | Script2 |
| 96 | Script3 |
| 97 | Script4 |
| 98 | Script5 |
| 99 | Script6 |
| 100 | Script7 |
| 101 | Script8 |
| 102 | Script9 |
| 103 | Script10 |
| 104 | Script11 |
| 105 | Script12 |
| 106 | Script13 |
| 107 | Script14 |
| 108 | Script15 |
| 109 | Script16 |
| 120 | NeoPixel1 |
| 121 | NeoPixel2 |
| 122 | NeoPixel3 |
| 123 | NeoPixel4 |
| 124 | RateRoll |
| 125 | RatePitch |
| 126 | RateThrust |
| 127 | RateYaw |
| 128 | WingSailElevator |
| 129 | ProfiLED1 |
| 130 | ProfiLED2 |
| 131 | ProfiLED3 |
| 132 | ProfiLEDClock |
| 133 | Winch Clutch |
| 134 | SERVOn_MIN |
| 135 | SERVOn_TRIM |
| 136 | SERVOn_MAX |
| 137 | SailMastRotation |
| 138 | Alarm |
| 139 | Alarm Inverted |
| 140 | RCIN1Scaled |
| 141 | RCIN2Scaled |
| 142 | RCIN3Scaled |
| 143 | RCIN4Scaled |
| 144 | RCIN5Scaled |
| 145 | RCIN6Scaled |
| 146 | RCIN7Scaled |
| 147 | RCIN8Scaled |
| 148 | RCIN9Scaled |
| 149 | RCIN10Scaled |
| 150 | RCIN11Scaled |
| 151 | RCIN12Scaled |
| 152 | RCIN13Scaled |
| 153 | RCIN14Scaled |
| 154 | RCIN15Scaled |
| 155 | RCIN16Scaled |
| 180 | CameraZoom |
minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Trim PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse servo operation. Set to 0 for normal operation. Set to 1 to reverse this output channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
Function assigned to this servo. Setting this to Disabled(0) will setup this output for control by auto missions or MAVLink servo set commands. any other value will enable the corresponding function
| Value | Meaning |
|---|---|
| -1 | GPIO |
| 0 | Disabled |
| 1 | RCPassThru |
| 2 | Flap |
| 3 | FlapAuto |
| 4 | Aileron |
| 6 | Mount1Yaw |
| 7 | Mount1Pitch |
| 8 | Mount1Roll |
| 9 | Mount1Retract |
| 10 | CameraTrigger |
| 12 | Mount2Yaw |
| 13 | Mount2Pitch |
| 14 | Mount2Roll |
| 15 | Mount2Retract |
| 16 | DifferentialSpoilerLeft1 |
| 17 | DifferentialSpoilerRight1 |
| 19 | Elevator |
| 21 | Rudder |
| 22 | SprayerPump |
| 23 | SprayerSpinner |
| 24 | FlaperonLeft |
| 25 | FlaperonRight |
| 26 | GroundSteering |
| 27 | Parachute |
| 28 | Gripper |
| 29 | LandingGear |
| 30 | EngineRunEnable |
| 31 | HeliRSC |
| 32 | HeliTailRSC |
| 33 | Motor1 |
| 34 | Motor2 |
| 35 | Motor3 |
| 36 | Motor4 |
| 37 | Motor5 |
| 38 | Motor6 |
| 39 | Motor7 |
| 40 | Motor8 |
| 41 | TiltMotorsFront |
| 45 | TiltMotorsRear |
| 46 | TiltMotorRearLeft |
| 47 | TiltMotorRearRight |
| 51 | RCIN1 |
| 52 | RCIN2 |
| 53 | RCIN3 |
| 54 | RCIN4 |
| 55 | RCIN5 |
| 56 | RCIN6 |
| 57 | RCIN7 |
| 58 | RCIN8 |
| 59 | RCIN9 |
| 60 | RCIN10 |
| 61 | RCIN11 |
| 62 | RCIN12 |
| 63 | RCIN13 |
| 64 | RCIN14 |
| 65 | RCIN15 |
| 66 | RCIN16 |
| 67 | Ignition |
| 69 | Starter |
| 70 | Throttle |
| 71 | TrackerYaw |
| 72 | TrackerPitch |
| 73 | ThrottleLeft |
| 74 | ThrottleRight |
| 75 | TiltMotorFrontLeft |
| 76 | TiltMotorFrontRight |
| 77 | ElevonLeft |
| 78 | ElevonRight |
| 79 | VTailLeft |
| 80 | VTailRight |
| 81 | BoostThrottle |
| 82 | Motor9 |
| 83 | Motor10 |
| 84 | Motor11 |
| 85 | Motor12 |
| 86 | DifferentialSpoilerLeft2 |
| 87 | DifferentialSpoilerRight2 |
| 88 | Winch |
| 89 | Main Sail |
| 90 | CameraISO |
| 91 | CameraAperture |
| 92 | CameraFocus |
| 93 | CameraShutterSpeed |
| 94 | Script1 |
| 95 | Script2 |
| 96 | Script3 |
| 97 | Script4 |
| 98 | Script5 |
| 99 | Script6 |
| 100 | Script7 |
| 101 | Script8 |
| 102 | Script9 |
| 103 | Script10 |
| 104 | Script11 |
| 105 | Script12 |
| 106 | Script13 |
| 107 | Script14 |
| 108 | Script15 |
| 109 | Script16 |
| 120 | NeoPixel1 |
| 121 | NeoPixel2 |
| 122 | NeoPixel3 |
| 123 | NeoPixel4 |
| 124 | RateRoll |
| 125 | RatePitch |
| 126 | RateThrust |
| 127 | RateYaw |
| 128 | WingSailElevator |
| 129 | ProfiLED1 |
| 130 | ProfiLED2 |
| 131 | ProfiLED3 |
| 132 | ProfiLEDClock |
| 133 | Winch Clutch |
| 134 | SERVOn_MIN |
| 135 | SERVOn_TRIM |
| 136 | SERVOn_MAX |
| 137 | SailMastRotation |
| 138 | Alarm |
| 139 | Alarm Inverted |
| 140 | RCIN1Scaled |
| 141 | RCIN2Scaled |
| 142 | RCIN3Scaled |
| 143 | RCIN4Scaled |
| 144 | RCIN5Scaled |
| 145 | RCIN6Scaled |
| 146 | RCIN7Scaled |
| 147 | RCIN8Scaled |
| 148 | RCIN9Scaled |
| 149 | RCIN10Scaled |
| 150 | RCIN11Scaled |
| 151 | RCIN12Scaled |
| 152 | RCIN13Scaled |
| 153 | RCIN14Scaled |
| 154 | RCIN15Scaled |
| 155 | RCIN16Scaled |
| 180 | CameraZoom |
minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Trim PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse servo operation. Set to 0 for normal operation. Set to 1 to reverse this output channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
Function assigned to this servo. Setting this to Disabled(0) will setup this output for control by auto missions or MAVLink servo set commands. any other value will enable the corresponding function
| Value | Meaning |
|---|---|
| -1 | GPIO |
| 0 | Disabled |
| 1 | RCPassThru |
| 2 | Flap |
| 3 | FlapAuto |
| 4 | Aileron |
| 6 | Mount1Yaw |
| 7 | Mount1Pitch |
| 8 | Mount1Roll |
| 9 | Mount1Retract |
| 10 | CameraTrigger |
| 12 | Mount2Yaw |
| 13 | Mount2Pitch |
| 14 | Mount2Roll |
| 15 | Mount2Retract |
| 16 | DifferentialSpoilerLeft1 |
| 17 | DifferentialSpoilerRight1 |
| 19 | Elevator |
| 21 | Rudder |
| 22 | SprayerPump |
| 23 | SprayerSpinner |
| 24 | FlaperonLeft |
| 25 | FlaperonRight |
| 26 | GroundSteering |
| 27 | Parachute |
| 28 | Gripper |
| 29 | LandingGear |
| 30 | EngineRunEnable |
| 31 | HeliRSC |
| 32 | HeliTailRSC |
| 33 | Motor1 |
| 34 | Motor2 |
| 35 | Motor3 |
| 36 | Motor4 |
| 37 | Motor5 |
| 38 | Motor6 |
| 39 | Motor7 |
| 40 | Motor8 |
| 41 | TiltMotorsFront |
| 45 | TiltMotorsRear |
| 46 | TiltMotorRearLeft |
| 47 | TiltMotorRearRight |
| 51 | RCIN1 |
| 52 | RCIN2 |
| 53 | RCIN3 |
| 54 | RCIN4 |
| 55 | RCIN5 |
| 56 | RCIN6 |
| 57 | RCIN7 |
| 58 | RCIN8 |
| 59 | RCIN9 |
| 60 | RCIN10 |
| 61 | RCIN11 |
| 62 | RCIN12 |
| 63 | RCIN13 |
| 64 | RCIN14 |
| 65 | RCIN15 |
| 66 | RCIN16 |
| 67 | Ignition |
| 69 | Starter |
| 70 | Throttle |
| 71 | TrackerYaw |
| 72 | TrackerPitch |
| 73 | ThrottleLeft |
| 74 | ThrottleRight |
| 75 | TiltMotorFrontLeft |
| 76 | TiltMotorFrontRight |
| 77 | ElevonLeft |
| 78 | ElevonRight |
| 79 | VTailLeft |
| 80 | VTailRight |
| 81 | BoostThrottle |
| 82 | Motor9 |
| 83 | Motor10 |
| 84 | Motor11 |
| 85 | Motor12 |
| 86 | DifferentialSpoilerLeft2 |
| 87 | DifferentialSpoilerRight2 |
| 88 | Winch |
| 89 | Main Sail |
| 90 | CameraISO |
| 91 | CameraAperture |
| 92 | CameraFocus |
| 93 | CameraShutterSpeed |
| 94 | Script1 |
| 95 | Script2 |
| 96 | Script3 |
| 97 | Script4 |
| 98 | Script5 |
| 99 | Script6 |
| 100 | Script7 |
| 101 | Script8 |
| 102 | Script9 |
| 103 | Script10 |
| 104 | Script11 |
| 105 | Script12 |
| 106 | Script13 |
| 107 | Script14 |
| 108 | Script15 |
| 109 | Script16 |
| 120 | NeoPixel1 |
| 121 | NeoPixel2 |
| 122 | NeoPixel3 |
| 123 | NeoPixel4 |
| 124 | RateRoll |
| 125 | RatePitch |
| 126 | RateThrust |
| 127 | RateYaw |
| 128 | WingSailElevator |
| 129 | ProfiLED1 |
| 130 | ProfiLED2 |
| 131 | ProfiLED3 |
| 132 | ProfiLEDClock |
| 133 | Winch Clutch |
| 134 | SERVOn_MIN |
| 135 | SERVOn_TRIM |
| 136 | SERVOn_MAX |
| 137 | SailMastRotation |
| 138 | Alarm |
| 139 | Alarm Inverted |
| 140 | RCIN1Scaled |
| 141 | RCIN2Scaled |
| 142 | RCIN3Scaled |
| 143 | RCIN4Scaled |
| 144 | RCIN5Scaled |
| 145 | RCIN6Scaled |
| 146 | RCIN7Scaled |
| 147 | RCIN8Scaled |
| 148 | RCIN9Scaled |
| 149 | RCIN10Scaled |
| 150 | RCIN11Scaled |
| 151 | RCIN12Scaled |
| 152 | RCIN13Scaled |
| 153 | RCIN14Scaled |
| 154 | RCIN15Scaled |
| 155 | RCIN16Scaled |
| 180 | CameraZoom |
minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Trim PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse servo operation. Set to 0 for normal operation. Set to 1 to reverse this output channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
Function assigned to this servo. Setting this to Disabled(0) will setup this output for control by auto missions or MAVLink servo set commands. any other value will enable the corresponding function
| Value | Meaning |
|---|---|
| -1 | GPIO |
| 0 | Disabled |
| 1 | RCPassThru |
| 2 | Flap |
| 3 | FlapAuto |
| 4 | Aileron |
| 6 | Mount1Yaw |
| 7 | Mount1Pitch |
| 8 | Mount1Roll |
| 9 | Mount1Retract |
| 10 | CameraTrigger |
| 12 | Mount2Yaw |
| 13 | Mount2Pitch |
| 14 | Mount2Roll |
| 15 | Mount2Retract |
| 16 | DifferentialSpoilerLeft1 |
| 17 | DifferentialSpoilerRight1 |
| 19 | Elevator |
| 21 | Rudder |
| 22 | SprayerPump |
| 23 | SprayerSpinner |
| 24 | FlaperonLeft |
| 25 | FlaperonRight |
| 26 | GroundSteering |
| 27 | Parachute |
| 28 | Gripper |
| 29 | LandingGear |
| 30 | EngineRunEnable |
| 31 | HeliRSC |
| 32 | HeliTailRSC |
| 33 | Motor1 |
| 34 | Motor2 |
| 35 | Motor3 |
| 36 | Motor4 |
| 37 | Motor5 |
| 38 | Motor6 |
| 39 | Motor7 |
| 40 | Motor8 |
| 41 | TiltMotorsFront |
| 45 | TiltMotorsRear |
| 46 | TiltMotorRearLeft |
| 47 | TiltMotorRearRight |
| 51 | RCIN1 |
| 52 | RCIN2 |
| 53 | RCIN3 |
| 54 | RCIN4 |
| 55 | RCIN5 |
| 56 | RCIN6 |
| 57 | RCIN7 |
| 58 | RCIN8 |
| 59 | RCIN9 |
| 60 | RCIN10 |
| 61 | RCIN11 |
| 62 | RCIN12 |
| 63 | RCIN13 |
| 64 | RCIN14 |
| 65 | RCIN15 |
| 66 | RCIN16 |
| 67 | Ignition |
| 69 | Starter |
| 70 | Throttle |
| 71 | TrackerYaw |
| 72 | TrackerPitch |
| 73 | ThrottleLeft |
| 74 | ThrottleRight |
| 75 | TiltMotorFrontLeft |
| 76 | TiltMotorFrontRight |
| 77 | ElevonLeft |
| 78 | ElevonRight |
| 79 | VTailLeft |
| 80 | VTailRight |
| 81 | BoostThrottle |
| 82 | Motor9 |
| 83 | Motor10 |
| 84 | Motor11 |
| 85 | Motor12 |
| 86 | DifferentialSpoilerLeft2 |
| 87 | DifferentialSpoilerRight2 |
| 88 | Winch |
| 89 | Main Sail |
| 90 | CameraISO |
| 91 | CameraAperture |
| 92 | CameraFocus |
| 93 | CameraShutterSpeed |
| 94 | Script1 |
| 95 | Script2 |
| 96 | Script3 |
| 97 | Script4 |
| 98 | Script5 |
| 99 | Script6 |
| 100 | Script7 |
| 101 | Script8 |
| 102 | Script9 |
| 103 | Script10 |
| 104 | Script11 |
| 105 | Script12 |
| 106 | Script13 |
| 107 | Script14 |
| 108 | Script15 |
| 109 | Script16 |
| 120 | NeoPixel1 |
| 121 | NeoPixel2 |
| 122 | NeoPixel3 |
| 123 | NeoPixel4 |
| 124 | RateRoll |
| 125 | RatePitch |
| 126 | RateThrust |
| 127 | RateYaw |
| 128 | WingSailElevator |
| 129 | ProfiLED1 |
| 130 | ProfiLED2 |
| 131 | ProfiLED3 |
| 132 | ProfiLEDClock |
| 133 | Winch Clutch |
| 134 | SERVOn_MIN |
| 135 | SERVOn_TRIM |
| 136 | SERVOn_MAX |
| 137 | SailMastRotation |
| 138 | Alarm |
| 139 | Alarm Inverted |
| 140 | RCIN1Scaled |
| 141 | RCIN2Scaled |
| 142 | RCIN3Scaled |
| 143 | RCIN4Scaled |
| 144 | RCIN5Scaled |
| 145 | RCIN6Scaled |
| 146 | RCIN7Scaled |
| 147 | RCIN8Scaled |
| 148 | RCIN9Scaled |
| 149 | RCIN10Scaled |
| 150 | RCIN11Scaled |
| 151 | RCIN12Scaled |
| 152 | RCIN13Scaled |
| 153 | RCIN14Scaled |
| 154 | RCIN15Scaled |
| 155 | RCIN16Scaled |
| 180 | CameraZoom |
minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Trim PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse servo operation. Set to 0 for normal operation. Set to 1 to reverse this output channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
Function assigned to this servo. Setting this to Disabled(0) will setup this output for control by auto missions or MAVLink servo set commands. any other value will enable the corresponding function
| Value | Meaning |
|---|---|
| -1 | GPIO |
| 0 | Disabled |
| 1 | RCPassThru |
| 2 | Flap |
| 3 | FlapAuto |
| 4 | Aileron |
| 6 | Mount1Yaw |
| 7 | Mount1Pitch |
| 8 | Mount1Roll |
| 9 | Mount1Retract |
| 10 | CameraTrigger |
| 12 | Mount2Yaw |
| 13 | Mount2Pitch |
| 14 | Mount2Roll |
| 15 | Mount2Retract |
| 16 | DifferentialSpoilerLeft1 |
| 17 | DifferentialSpoilerRight1 |
| 19 | Elevator |
| 21 | Rudder |
| 22 | SprayerPump |
| 23 | SprayerSpinner |
| 24 | FlaperonLeft |
| 25 | FlaperonRight |
| 26 | GroundSteering |
| 27 | Parachute |
| 28 | Gripper |
| 29 | LandingGear |
| 30 | EngineRunEnable |
| 31 | HeliRSC |
| 32 | HeliTailRSC |
| 33 | Motor1 |
| 34 | Motor2 |
| 35 | Motor3 |
| 36 | Motor4 |
| 37 | Motor5 |
| 38 | Motor6 |
| 39 | Motor7 |
| 40 | Motor8 |
| 41 | TiltMotorsFront |
| 45 | TiltMotorsRear |
| 46 | TiltMotorRearLeft |
| 47 | TiltMotorRearRight |
| 51 | RCIN1 |
| 52 | RCIN2 |
| 53 | RCIN3 |
| 54 | RCIN4 |
| 55 | RCIN5 |
| 56 | RCIN6 |
| 57 | RCIN7 |
| 58 | RCIN8 |
| 59 | RCIN9 |
| 60 | RCIN10 |
| 61 | RCIN11 |
| 62 | RCIN12 |
| 63 | RCIN13 |
| 64 | RCIN14 |
| 65 | RCIN15 |
| 66 | RCIN16 |
| 67 | Ignition |
| 69 | Starter |
| 70 | Throttle |
| 71 | TrackerYaw |
| 72 | TrackerPitch |
| 73 | ThrottleLeft |
| 74 | ThrottleRight |
| 75 | TiltMotorFrontLeft |
| 76 | TiltMotorFrontRight |
| 77 | ElevonLeft |
| 78 | ElevonRight |
| 79 | VTailLeft |
| 80 | VTailRight |
| 81 | BoostThrottle |
| 82 | Motor9 |
| 83 | Motor10 |
| 84 | Motor11 |
| 85 | Motor12 |
| 86 | DifferentialSpoilerLeft2 |
| 87 | DifferentialSpoilerRight2 |
| 88 | Winch |
| 89 | Main Sail |
| 90 | CameraISO |
| 91 | CameraAperture |
| 92 | CameraFocus |
| 93 | CameraShutterSpeed |
| 94 | Script1 |
| 95 | Script2 |
| 96 | Script3 |
| 97 | Script4 |
| 98 | Script5 |
| 99 | Script6 |
| 100 | Script7 |
| 101 | Script8 |
| 102 | Script9 |
| 103 | Script10 |
| 104 | Script11 |
| 105 | Script12 |
| 106 | Script13 |
| 107 | Script14 |
| 108 | Script15 |
| 109 | Script16 |
| 120 | NeoPixel1 |
| 121 | NeoPixel2 |
| 122 | NeoPixel3 |
| 123 | NeoPixel4 |
| 124 | RateRoll |
| 125 | RatePitch |
| 126 | RateThrust |
| 127 | RateYaw |
| 128 | WingSailElevator |
| 129 | ProfiLED1 |
| 130 | ProfiLED2 |
| 131 | ProfiLED3 |
| 132 | ProfiLEDClock |
| 133 | Winch Clutch |
| 134 | SERVOn_MIN |
| 135 | SERVOn_TRIM |
| 136 | SERVOn_MAX |
| 137 | SailMastRotation |
| 138 | Alarm |
| 139 | Alarm Inverted |
| 140 | RCIN1Scaled |
| 141 | RCIN2Scaled |
| 142 | RCIN3Scaled |
| 143 | RCIN4Scaled |
| 144 | RCIN5Scaled |
| 145 | RCIN6Scaled |
| 146 | RCIN7Scaled |
| 147 | RCIN8Scaled |
| 148 | RCIN9Scaled |
| 149 | RCIN10Scaled |
| 150 | RCIN11Scaled |
| 151 | RCIN12Scaled |
| 152 | RCIN13Scaled |
| 153 | RCIN14Scaled |
| 154 | RCIN15Scaled |
| 155 | RCIN16Scaled |
| 180 | CameraZoom |
minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Trim PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse servo operation. Set to 0 for normal operation. Set to 1 to reverse this output channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
Function assigned to this servo. Setting this to Disabled(0) will setup this output for control by auto missions or MAVLink servo set commands. any other value will enable the corresponding function
| Value | Meaning |
|---|---|
| -1 | GPIO |
| 0 | Disabled |
| 1 | RCPassThru |
| 2 | Flap |
| 3 | FlapAuto |
| 4 | Aileron |
| 6 | Mount1Yaw |
| 7 | Mount1Pitch |
| 8 | Mount1Roll |
| 9 | Mount1Retract |
| 10 | CameraTrigger |
| 12 | Mount2Yaw |
| 13 | Mount2Pitch |
| 14 | Mount2Roll |
| 15 | Mount2Retract |
| 16 | DifferentialSpoilerLeft1 |
| 17 | DifferentialSpoilerRight1 |
| 19 | Elevator |
| 21 | Rudder |
| 22 | SprayerPump |
| 23 | SprayerSpinner |
| 24 | FlaperonLeft |
| 25 | FlaperonRight |
| 26 | GroundSteering |
| 27 | Parachute |
| 28 | Gripper |
| 29 | LandingGear |
| 30 | EngineRunEnable |
| 31 | HeliRSC |
| 32 | HeliTailRSC |
| 33 | Motor1 |
| 34 | Motor2 |
| 35 | Motor3 |
| 36 | Motor4 |
| 37 | Motor5 |
| 38 | Motor6 |
| 39 | Motor7 |
| 40 | Motor8 |
| 41 | TiltMotorsFront |
| 45 | TiltMotorsRear |
| 46 | TiltMotorRearLeft |
| 47 | TiltMotorRearRight |
| 51 | RCIN1 |
| 52 | RCIN2 |
| 53 | RCIN3 |
| 54 | RCIN4 |
| 55 | RCIN5 |
| 56 | RCIN6 |
| 57 | RCIN7 |
| 58 | RCIN8 |
| 59 | RCIN9 |
| 60 | RCIN10 |
| 61 | RCIN11 |
| 62 | RCIN12 |
| 63 | RCIN13 |
| 64 | RCIN14 |
| 65 | RCIN15 |
| 66 | RCIN16 |
| 67 | Ignition |
| 69 | Starter |
| 70 | Throttle |
| 71 | TrackerYaw |
| 72 | TrackerPitch |
| 73 | ThrottleLeft |
| 74 | ThrottleRight |
| 75 | TiltMotorFrontLeft |
| 76 | TiltMotorFrontRight |
| 77 | ElevonLeft |
| 78 | ElevonRight |
| 79 | VTailLeft |
| 80 | VTailRight |
| 81 | BoostThrottle |
| 82 | Motor9 |
| 83 | Motor10 |
| 84 | Motor11 |
| 85 | Motor12 |
| 86 | DifferentialSpoilerLeft2 |
| 87 | DifferentialSpoilerRight2 |
| 88 | Winch |
| 89 | Main Sail |
| 90 | CameraISO |
| 91 | CameraAperture |
| 92 | CameraFocus |
| 93 | CameraShutterSpeed |
| 94 | Script1 |
| 95 | Script2 |
| 96 | Script3 |
| 97 | Script4 |
| 98 | Script5 |
| 99 | Script6 |
| 100 | Script7 |
| 101 | Script8 |
| 102 | Script9 |
| 103 | Script10 |
| 104 | Script11 |
| 105 | Script12 |
| 106 | Script13 |
| 107 | Script14 |
| 108 | Script15 |
| 109 | Script16 |
| 120 | NeoPixel1 |
| 121 | NeoPixel2 |
| 122 | NeoPixel3 |
| 123 | NeoPixel4 |
| 124 | RateRoll |
| 125 | RatePitch |
| 126 | RateThrust |
| 127 | RateYaw |
| 128 | WingSailElevator |
| 129 | ProfiLED1 |
| 130 | ProfiLED2 |
| 131 | ProfiLED3 |
| 132 | ProfiLEDClock |
| 133 | Winch Clutch |
| 134 | SERVOn_MIN |
| 135 | SERVOn_TRIM |
| 136 | SERVOn_MAX |
| 137 | SailMastRotation |
| 138 | Alarm |
| 139 | Alarm Inverted |
| 140 | RCIN1Scaled |
| 141 | RCIN2Scaled |
| 142 | RCIN3Scaled |
| 143 | RCIN4Scaled |
| 144 | RCIN5Scaled |
| 145 | RCIN6Scaled |
| 146 | RCIN7Scaled |
| 147 | RCIN8Scaled |
| 148 | RCIN9Scaled |
| 149 | RCIN10Scaled |
| 150 | RCIN11Scaled |
| 151 | RCIN12Scaled |
| 152 | RCIN13Scaled |
| 153 | RCIN14Scaled |
| 154 | RCIN15Scaled |
| 155 | RCIN16Scaled |
| 180 | CameraZoom |
minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Trim PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse servo operation. Set to 0 for normal operation. Set to 1 to reverse this output channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
Function assigned to this servo. Setting this to Disabled(0) will setup this output for control by auto missions or MAVLink servo set commands. any other value will enable the corresponding function
| Value | Meaning |
|---|---|
| -1 | GPIO |
| 0 | Disabled |
| 1 | RCPassThru |
| 2 | Flap |
| 3 | FlapAuto |
| 4 | Aileron |
| 6 | Mount1Yaw |
| 7 | Mount1Pitch |
| 8 | Mount1Roll |
| 9 | Mount1Retract |
| 10 | CameraTrigger |
| 12 | Mount2Yaw |
| 13 | Mount2Pitch |
| 14 | Mount2Roll |
| 15 | Mount2Retract |
| 16 | DifferentialSpoilerLeft1 |
| 17 | DifferentialSpoilerRight1 |
| 19 | Elevator |
| 21 | Rudder |
| 22 | SprayerPump |
| 23 | SprayerSpinner |
| 24 | FlaperonLeft |
| 25 | FlaperonRight |
| 26 | GroundSteering |
| 27 | Parachute |
| 28 | Gripper |
| 29 | LandingGear |
| 30 | EngineRunEnable |
| 31 | HeliRSC |
| 32 | HeliTailRSC |
| 33 | Motor1 |
| 34 | Motor2 |
| 35 | Motor3 |
| 36 | Motor4 |
| 37 | Motor5 |
| 38 | Motor6 |
| 39 | Motor7 |
| 40 | Motor8 |
| 41 | TiltMotorsFront |
| 45 | TiltMotorsRear |
| 46 | TiltMotorRearLeft |
| 47 | TiltMotorRearRight |
| 51 | RCIN1 |
| 52 | RCIN2 |
| 53 | RCIN3 |
| 54 | RCIN4 |
| 55 | RCIN5 |
| 56 | RCIN6 |
| 57 | RCIN7 |
| 58 | RCIN8 |
| 59 | RCIN9 |
| 60 | RCIN10 |
| 61 | RCIN11 |
| 62 | RCIN12 |
| 63 | RCIN13 |
| 64 | RCIN14 |
| 65 | RCIN15 |
| 66 | RCIN16 |
| 67 | Ignition |
| 69 | Starter |
| 70 | Throttle |
| 71 | TrackerYaw |
| 72 | TrackerPitch |
| 73 | ThrottleLeft |
| 74 | ThrottleRight |
| 75 | TiltMotorFrontLeft |
| 76 | TiltMotorFrontRight |
| 77 | ElevonLeft |
| 78 | ElevonRight |
| 79 | VTailLeft |
| 80 | VTailRight |
| 81 | BoostThrottle |
| 82 | Motor9 |
| 83 | Motor10 |
| 84 | Motor11 |
| 85 | Motor12 |
| 86 | DifferentialSpoilerLeft2 |
| 87 | DifferentialSpoilerRight2 |
| 88 | Winch |
| 89 | Main Sail |
| 90 | CameraISO |
| 91 | CameraAperture |
| 92 | CameraFocus |
| 93 | CameraShutterSpeed |
| 94 | Script1 |
| 95 | Script2 |
| 96 | Script3 |
| 97 | Script4 |
| 98 | Script5 |
| 99 | Script6 |
| 100 | Script7 |
| 101 | Script8 |
| 102 | Script9 |
| 103 | Script10 |
| 104 | Script11 |
| 105 | Script12 |
| 106 | Script13 |
| 107 | Script14 |
| 108 | Script15 |
| 109 | Script16 |
| 120 | NeoPixel1 |
| 121 | NeoPixel2 |
| 122 | NeoPixel3 |
| 123 | NeoPixel4 |
| 124 | RateRoll |
| 125 | RatePitch |
| 126 | RateThrust |
| 127 | RateYaw |
| 128 | WingSailElevator |
| 129 | ProfiLED1 |
| 130 | ProfiLED2 |
| 131 | ProfiLED3 |
| 132 | ProfiLEDClock |
| 133 | Winch Clutch |
| 134 | SERVOn_MIN |
| 135 | SERVOn_TRIM |
| 136 | SERVOn_MAX |
| 137 | SailMastRotation |
| 138 | Alarm |
| 139 | Alarm Inverted |
| 140 | RCIN1Scaled |
| 141 | RCIN2Scaled |
| 142 | RCIN3Scaled |
| 143 | RCIN4Scaled |
| 144 | RCIN5Scaled |
| 145 | RCIN6Scaled |
| 146 | RCIN7Scaled |
| 147 | RCIN8Scaled |
| 148 | RCIN9Scaled |
| 149 | RCIN10Scaled |
| 150 | RCIN11Scaled |
| 151 | RCIN12Scaled |
| 152 | RCIN13Scaled |
| 153 | RCIN14Scaled |
| 154 | RCIN15Scaled |
| 155 | RCIN16Scaled |
| 180 | CameraZoom |
minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Trim PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse servo operation. Set to 0 for normal operation. Set to 1 to reverse this output channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
Function assigned to this servo. Setting this to Disabled(0) will setup this output for control by auto missions or MAVLink servo set commands. any other value will enable the corresponding function
| Value | Meaning |
|---|---|
| -1 | GPIO |
| 0 | Disabled |
| 1 | RCPassThru |
| 2 | Flap |
| 3 | FlapAuto |
| 4 | Aileron |
| 6 | Mount1Yaw |
| 7 | Mount1Pitch |
| 8 | Mount1Roll |
| 9 | Mount1Retract |
| 10 | CameraTrigger |
| 12 | Mount2Yaw |
| 13 | Mount2Pitch |
| 14 | Mount2Roll |
| 15 | Mount2Retract |
| 16 | DifferentialSpoilerLeft1 |
| 17 | DifferentialSpoilerRight1 |
| 19 | Elevator |
| 21 | Rudder |
| 22 | SprayerPump |
| 23 | SprayerSpinner |
| 24 | FlaperonLeft |
| 25 | FlaperonRight |
| 26 | GroundSteering |
| 27 | Parachute |
| 28 | Gripper |
| 29 | LandingGear |
| 30 | EngineRunEnable |
| 31 | HeliRSC |
| 32 | HeliTailRSC |
| 33 | Motor1 |
| 34 | Motor2 |
| 35 | Motor3 |
| 36 | Motor4 |
| 37 | Motor5 |
| 38 | Motor6 |
| 39 | Motor7 |
| 40 | Motor8 |
| 41 | TiltMotorsFront |
| 45 | TiltMotorsRear |
| 46 | TiltMotorRearLeft |
| 47 | TiltMotorRearRight |
| 51 | RCIN1 |
| 52 | RCIN2 |
| 53 | RCIN3 |
| 54 | RCIN4 |
| 55 | RCIN5 |
| 56 | RCIN6 |
| 57 | RCIN7 |
| 58 | RCIN8 |
| 59 | RCIN9 |
| 60 | RCIN10 |
| 61 | RCIN11 |
| 62 | RCIN12 |
| 63 | RCIN13 |
| 64 | RCIN14 |
| 65 | RCIN15 |
| 66 | RCIN16 |
| 67 | Ignition |
| 69 | Starter |
| 70 | Throttle |
| 71 | TrackerYaw |
| 72 | TrackerPitch |
| 73 | ThrottleLeft |
| 74 | ThrottleRight |
| 75 | TiltMotorFrontLeft |
| 76 | TiltMotorFrontRight |
| 77 | ElevonLeft |
| 78 | ElevonRight |
| 79 | VTailLeft |
| 80 | VTailRight |
| 81 | BoostThrottle |
| 82 | Motor9 |
| 83 | Motor10 |
| 84 | Motor11 |
| 85 | Motor12 |
| 86 | DifferentialSpoilerLeft2 |
| 87 | DifferentialSpoilerRight2 |
| 88 | Winch |
| 89 | Main Sail |
| 90 | CameraISO |
| 91 | CameraAperture |
| 92 | CameraFocus |
| 93 | CameraShutterSpeed |
| 94 | Script1 |
| 95 | Script2 |
| 96 | Script3 |
| 97 | Script4 |
| 98 | Script5 |
| 99 | Script6 |
| 100 | Script7 |
| 101 | Script8 |
| 102 | Script9 |
| 103 | Script10 |
| 104 | Script11 |
| 105 | Script12 |
| 106 | Script13 |
| 107 | Script14 |
| 108 | Script15 |
| 109 | Script16 |
| 120 | NeoPixel1 |
| 121 | NeoPixel2 |
| 122 | NeoPixel3 |
| 123 | NeoPixel4 |
| 124 | RateRoll |
| 125 | RatePitch |
| 126 | RateThrust |
| 127 | RateYaw |
| 128 | WingSailElevator |
| 129 | ProfiLED1 |
| 130 | ProfiLED2 |
| 131 | ProfiLED3 |
| 132 | ProfiLEDClock |
| 133 | Winch Clutch |
| 134 | SERVOn_MIN |
| 135 | SERVOn_TRIM |
| 136 | SERVOn_MAX |
| 137 | SailMastRotation |
| 138 | Alarm |
| 139 | Alarm Inverted |
| 140 | RCIN1Scaled |
| 141 | RCIN2Scaled |
| 142 | RCIN3Scaled |
| 143 | RCIN4Scaled |
| 144 | RCIN5Scaled |
| 145 | RCIN6Scaled |
| 146 | RCIN7Scaled |
| 147 | RCIN8Scaled |
| 148 | RCIN9Scaled |
| 149 | RCIN10Scaled |
| 150 | RCIN11Scaled |
| 151 | RCIN12Scaled |
| 152 | RCIN13Scaled |
| 153 | RCIN14Scaled |
| 154 | RCIN15Scaled |
| 155 | RCIN16Scaled |
| 180 | CameraZoom |
minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Trim PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse servo operation. Set to 0 for normal operation. Set to 1 to reverse this output channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
Function assigned to this servo. Setting this to Disabled(0) will setup this output for control by auto missions or MAVLink servo set commands. any other value will enable the corresponding function
| Value | Meaning |
|---|---|
| -1 | GPIO |
| 0 | Disabled |
| 1 | RCPassThru |
| 2 | Flap |
| 3 | FlapAuto |
| 4 | Aileron |
| 6 | Mount1Yaw |
| 7 | Mount1Pitch |
| 8 | Mount1Roll |
| 9 | Mount1Retract |
| 10 | CameraTrigger |
| 12 | Mount2Yaw |
| 13 | Mount2Pitch |
| 14 | Mount2Roll |
| 15 | Mount2Retract |
| 16 | DifferentialSpoilerLeft1 |
| 17 | DifferentialSpoilerRight1 |
| 19 | Elevator |
| 21 | Rudder |
| 22 | SprayerPump |
| 23 | SprayerSpinner |
| 24 | FlaperonLeft |
| 25 | FlaperonRight |
| 26 | GroundSteering |
| 27 | Parachute |
| 28 | Gripper |
| 29 | LandingGear |
| 30 | EngineRunEnable |
| 31 | HeliRSC |
| 32 | HeliTailRSC |
| 33 | Motor1 |
| 34 | Motor2 |
| 35 | Motor3 |
| 36 | Motor4 |
| 37 | Motor5 |
| 38 | Motor6 |
| 39 | Motor7 |
| 40 | Motor8 |
| 41 | TiltMotorsFront |
| 45 | TiltMotorsRear |
| 46 | TiltMotorRearLeft |
| 47 | TiltMotorRearRight |
| 51 | RCIN1 |
| 52 | RCIN2 |
| 53 | RCIN3 |
| 54 | RCIN4 |
| 55 | RCIN5 |
| 56 | RCIN6 |
| 57 | RCIN7 |
| 58 | RCIN8 |
| 59 | RCIN9 |
| 60 | RCIN10 |
| 61 | RCIN11 |
| 62 | RCIN12 |
| 63 | RCIN13 |
| 64 | RCIN14 |
| 65 | RCIN15 |
| 66 | RCIN16 |
| 67 | Ignition |
| 69 | Starter |
| 70 | Throttle |
| 71 | TrackerYaw |
| 72 | TrackerPitch |
| 73 | ThrottleLeft |
| 74 | ThrottleRight |
| 75 | TiltMotorFrontLeft |
| 76 | TiltMotorFrontRight |
| 77 | ElevonLeft |
| 78 | ElevonRight |
| 79 | VTailLeft |
| 80 | VTailRight |
| 81 | BoostThrottle |
| 82 | Motor9 |
| 83 | Motor10 |
| 84 | Motor11 |
| 85 | Motor12 |
| 86 | DifferentialSpoilerLeft2 |
| 87 | DifferentialSpoilerRight2 |
| 88 | Winch |
| 89 | Main Sail |
| 90 | CameraISO |
| 91 | CameraAperture |
| 92 | CameraFocus |
| 93 | CameraShutterSpeed |
| 94 | Script1 |
| 95 | Script2 |
| 96 | Script3 |
| 97 | Script4 |
| 98 | Script5 |
| 99 | Script6 |
| 100 | Script7 |
| 101 | Script8 |
| 102 | Script9 |
| 103 | Script10 |
| 104 | Script11 |
| 105 | Script12 |
| 106 | Script13 |
| 107 | Script14 |
| 108 | Script15 |
| 109 | Script16 |
| 120 | NeoPixel1 |
| 121 | NeoPixel2 |
| 122 | NeoPixel3 |
| 123 | NeoPixel4 |
| 124 | RateRoll |
| 125 | RatePitch |
| 126 | RateThrust |
| 127 | RateYaw |
| 128 | WingSailElevator |
| 129 | ProfiLED1 |
| 130 | ProfiLED2 |
| 131 | ProfiLED3 |
| 132 | ProfiLEDClock |
| 133 | Winch Clutch |
| 134 | SERVOn_MIN |
| 135 | SERVOn_TRIM |
| 136 | SERVOn_MAX |
| 137 | SailMastRotation |
| 138 | Alarm |
| 139 | Alarm Inverted |
| 140 | RCIN1Scaled |
| 141 | RCIN2Scaled |
| 142 | RCIN3Scaled |
| 143 | RCIN4Scaled |
| 144 | RCIN5Scaled |
| 145 | RCIN6Scaled |
| 146 | RCIN7Scaled |
| 147 | RCIN8Scaled |
| 148 | RCIN9Scaled |
| 149 | RCIN10Scaled |
| 150 | RCIN11Scaled |
| 151 | RCIN12Scaled |
| 152 | RCIN13Scaled |
| 153 | RCIN14Scaled |
| 154 | RCIN15Scaled |
| 155 | RCIN16Scaled |
| 180 | CameraZoom |
minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Trim PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse servo operation. Set to 0 for normal operation. Set to 1 to reverse this output channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
Function assigned to this servo. Setting this to Disabled(0) will setup this output for control by auto missions or MAVLink servo set commands. any other value will enable the corresponding function
| Value | Meaning |
|---|---|
| -1 | GPIO |
| 0 | Disabled |
| 1 | RCPassThru |
| 2 | Flap |
| 3 | FlapAuto |
| 4 | Aileron |
| 6 | Mount1Yaw |
| 7 | Mount1Pitch |
| 8 | Mount1Roll |
| 9 | Mount1Retract |
| 10 | CameraTrigger |
| 12 | Mount2Yaw |
| 13 | Mount2Pitch |
| 14 | Mount2Roll |
| 15 | Mount2Retract |
| 16 | DifferentialSpoilerLeft1 |
| 17 | DifferentialSpoilerRight1 |
| 19 | Elevator |
| 21 | Rudder |
| 22 | SprayerPump |
| 23 | SprayerSpinner |
| 24 | FlaperonLeft |
| 25 | FlaperonRight |
| 26 | GroundSteering |
| 27 | Parachute |
| 28 | Gripper |
| 29 | LandingGear |
| 30 | EngineRunEnable |
| 31 | HeliRSC |
| 32 | HeliTailRSC |
| 33 | Motor1 |
| 34 | Motor2 |
| 35 | Motor3 |
| 36 | Motor4 |
| 37 | Motor5 |
| 38 | Motor6 |
| 39 | Motor7 |
| 40 | Motor8 |
| 41 | TiltMotorsFront |
| 45 | TiltMotorsRear |
| 46 | TiltMotorRearLeft |
| 47 | TiltMotorRearRight |
| 51 | RCIN1 |
| 52 | RCIN2 |
| 53 | RCIN3 |
| 54 | RCIN4 |
| 55 | RCIN5 |
| 56 | RCIN6 |
| 57 | RCIN7 |
| 58 | RCIN8 |
| 59 | RCIN9 |
| 60 | RCIN10 |
| 61 | RCIN11 |
| 62 | RCIN12 |
| 63 | RCIN13 |
| 64 | RCIN14 |
| 65 | RCIN15 |
| 66 | RCIN16 |
| 67 | Ignition |
| 69 | Starter |
| 70 | Throttle |
| 71 | TrackerYaw |
| 72 | TrackerPitch |
| 73 | ThrottleLeft |
| 74 | ThrottleRight |
| 75 | TiltMotorFrontLeft |
| 76 | TiltMotorFrontRight |
| 77 | ElevonLeft |
| 78 | ElevonRight |
| 79 | VTailLeft |
| 80 | VTailRight |
| 81 | BoostThrottle |
| 82 | Motor9 |
| 83 | Motor10 |
| 84 | Motor11 |
| 85 | Motor12 |
| 86 | DifferentialSpoilerLeft2 |
| 87 | DifferentialSpoilerRight2 |
| 88 | Winch |
| 89 | Main Sail |
| 90 | CameraISO |
| 91 | CameraAperture |
| 92 | CameraFocus |
| 93 | CameraShutterSpeed |
| 94 | Script1 |
| 95 | Script2 |
| 96 | Script3 |
| 97 | Script4 |
| 98 | Script5 |
| 99 | Script6 |
| 100 | Script7 |
| 101 | Script8 |
| 102 | Script9 |
| 103 | Script10 |
| 104 | Script11 |
| 105 | Script12 |
| 106 | Script13 |
| 107 | Script14 |
| 108 | Script15 |
| 109 | Script16 |
| 120 | NeoPixel1 |
| 121 | NeoPixel2 |
| 122 | NeoPixel3 |
| 123 | NeoPixel4 |
| 124 | RateRoll |
| 125 | RatePitch |
| 126 | RateThrust |
| 127 | RateYaw |
| 128 | WingSailElevator |
| 129 | ProfiLED1 |
| 130 | ProfiLED2 |
| 131 | ProfiLED3 |
| 132 | ProfiLEDClock |
| 133 | Winch Clutch |
| 134 | SERVOn_MIN |
| 135 | SERVOn_TRIM |
| 136 | SERVOn_MAX |
| 137 | SailMastRotation |
| 138 | Alarm |
| 139 | Alarm Inverted |
| 140 | RCIN1Scaled |
| 141 | RCIN2Scaled |
| 142 | RCIN3Scaled |
| 143 | RCIN4Scaled |
| 144 | RCIN5Scaled |
| 145 | RCIN6Scaled |
| 146 | RCIN7Scaled |
| 147 | RCIN8Scaled |
| 148 | RCIN9Scaled |
| 149 | RCIN10Scaled |
| 150 | RCIN11Scaled |
| 151 | RCIN12Scaled |
| 152 | RCIN13Scaled |
| 153 | RCIN14Scaled |
| 154 | RCIN15Scaled |
| 155 | RCIN16Scaled |
| 180 | CameraZoom |
minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Trim PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse servo operation. Set to 0 for normal operation. Set to 1 to reverse this output channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
Function assigned to this servo. Setting this to Disabled(0) will setup this output for control by auto missions or MAVLink servo set commands. any other value will enable the corresponding function
| Value | Meaning |
|---|---|
| -1 | GPIO |
| 0 | Disabled |
| 1 | RCPassThru |
| 2 | Flap |
| 3 | FlapAuto |
| 4 | Aileron |
| 6 | Mount1Yaw |
| 7 | Mount1Pitch |
| 8 | Mount1Roll |
| 9 | Mount1Retract |
| 10 | CameraTrigger |
| 12 | Mount2Yaw |
| 13 | Mount2Pitch |
| 14 | Mount2Roll |
| 15 | Mount2Retract |
| 16 | DifferentialSpoilerLeft1 |
| 17 | DifferentialSpoilerRight1 |
| 19 | Elevator |
| 21 | Rudder |
| 22 | SprayerPump |
| 23 | SprayerSpinner |
| 24 | FlaperonLeft |
| 25 | FlaperonRight |
| 26 | GroundSteering |
| 27 | Parachute |
| 28 | Gripper |
| 29 | LandingGear |
| 30 | EngineRunEnable |
| 31 | HeliRSC |
| 32 | HeliTailRSC |
| 33 | Motor1 |
| 34 | Motor2 |
| 35 | Motor3 |
| 36 | Motor4 |
| 37 | Motor5 |
| 38 | Motor6 |
| 39 | Motor7 |
| 40 | Motor8 |
| 41 | TiltMotorsFront |
| 45 | TiltMotorsRear |
| 46 | TiltMotorRearLeft |
| 47 | TiltMotorRearRight |
| 51 | RCIN1 |
| 52 | RCIN2 |
| 53 | RCIN3 |
| 54 | RCIN4 |
| 55 | RCIN5 |
| 56 | RCIN6 |
| 57 | RCIN7 |
| 58 | RCIN8 |
| 59 | RCIN9 |
| 60 | RCIN10 |
| 61 | RCIN11 |
| 62 | RCIN12 |
| 63 | RCIN13 |
| 64 | RCIN14 |
| 65 | RCIN15 |
| 66 | RCIN16 |
| 67 | Ignition |
| 69 | Starter |
| 70 | Throttle |
| 71 | TrackerYaw |
| 72 | TrackerPitch |
| 73 | ThrottleLeft |
| 74 | ThrottleRight |
| 75 | TiltMotorFrontLeft |
| 76 | TiltMotorFrontRight |
| 77 | ElevonLeft |
| 78 | ElevonRight |
| 79 | VTailLeft |
| 80 | VTailRight |
| 81 | BoostThrottle |
| 82 | Motor9 |
| 83 | Motor10 |
| 84 | Motor11 |
| 85 | Motor12 |
| 86 | DifferentialSpoilerLeft2 |
| 87 | DifferentialSpoilerRight2 |
| 88 | Winch |
| 89 | Main Sail |
| 90 | CameraISO |
| 91 | CameraAperture |
| 92 | CameraFocus |
| 93 | CameraShutterSpeed |
| 94 | Script1 |
| 95 | Script2 |
| 96 | Script3 |
| 97 | Script4 |
| 98 | Script5 |
| 99 | Script6 |
| 100 | Script7 |
| 101 | Script8 |
| 102 | Script9 |
| 103 | Script10 |
| 104 | Script11 |
| 105 | Script12 |
| 106 | Script13 |
| 107 | Script14 |
| 108 | Script15 |
| 109 | Script16 |
| 120 | NeoPixel1 |
| 121 | NeoPixel2 |
| 122 | NeoPixel3 |
| 123 | NeoPixel4 |
| 124 | RateRoll |
| 125 | RatePitch |
| 126 | RateThrust |
| 127 | RateYaw |
| 128 | WingSailElevator |
| 129 | ProfiLED1 |
| 130 | ProfiLED2 |
| 131 | ProfiLED3 |
| 132 | ProfiLEDClock |
| 133 | Winch Clutch |
| 134 | SERVOn_MIN |
| 135 | SERVOn_TRIM |
| 136 | SERVOn_MAX |
| 137 | SailMastRotation |
| 138 | Alarm |
| 139 | Alarm Inverted |
| 140 | RCIN1Scaled |
| 141 | RCIN2Scaled |
| 142 | RCIN3Scaled |
| 143 | RCIN4Scaled |
| 144 | RCIN5Scaled |
| 145 | RCIN6Scaled |
| 146 | RCIN7Scaled |
| 147 | RCIN8Scaled |
| 148 | RCIN9Scaled |
| 149 | RCIN10Scaled |
| 150 | RCIN11Scaled |
| 151 | RCIN12Scaled |
| 152 | RCIN13Scaled |
| 153 | RCIN14Scaled |
| 154 | RCIN15Scaled |
| 155 | RCIN16Scaled |
| 180 | CameraZoom |
minimum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
maximum PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Trim PWM pulse width in microseconds. Typically 1000 is lower limit, 1500 is neutral and 2000 is upper limit.
Reverse servo operation. Set to 0 for normal operation. Set to 1 to reverse this output channel.
| Value | Meaning |
|---|---|
| 0 | Normal |
| 1 | Reversed |
Function assigned to this servo. Setting this to Disabled(0) will setup this output for control by auto missions or MAVLink servo set commands. any other value will enable the corresponding function
| Value | Meaning |
|---|---|
| -1 | GPIO |
| 0 | Disabled |
| 1 | RCPassThru |
| 2 | Flap |
| 3 | FlapAuto |
| 4 | Aileron |
| 6 | Mount1Yaw |
| 7 | Mount1Pitch |
| 8 | Mount1Roll |
| 9 | Mount1Retract |
| 10 | CameraTrigger |
| 12 | Mount2Yaw |
| 13 | Mount2Pitch |
| 14 | Mount2Roll |
| 15 | Mount2Retract |
| 16 | DifferentialSpoilerLeft1 |
| 17 | DifferentialSpoilerRight1 |
| 19 | Elevator |
| 21 | Rudder |
| 22 | SprayerPump |
| 23 | SprayerSpinner |
| 24 | FlaperonLeft |
| 25 | FlaperonRight |
| 26 | GroundSteering |
| 27 | Parachute |
| 28 | Gripper |
| 29 | LandingGear |
| 30 | EngineRunEnable |
| 31 | HeliRSC |
| 32 | HeliTailRSC |
| 33 | Motor1 |
| 34 | Motor2 |
| 35 | Motor3 |
| 36 | Motor4 |
| 37 | Motor5 |
| 38 | Motor6 |
| 39 | Motor7 |
| 40 | Motor8 |
| 41 | TiltMotorsFront |
| 45 | TiltMotorsRear |
| 46 | TiltMotorRearLeft |
| 47 | TiltMotorRearRight |
| 51 | RCIN1 |
| 52 | RCIN2 |
| 53 | RCIN3 |
| 54 | RCIN4 |
| 55 | RCIN5 |
| 56 | RCIN6 |
| 57 | RCIN7 |
| 58 | RCIN8 |
| 59 | RCIN9 |
| 60 | RCIN10 |
| 61 | RCIN11 |
| 62 | RCIN12 |
| 63 | RCIN13 |
| 64 | RCIN14 |
| 65 | RCIN15 |
| 66 | RCIN16 |
| 67 | Ignition |
| 69 | Starter |
| 70 | Throttle |
| 71 | TrackerYaw |
| 72 | TrackerPitch |
| 73 | ThrottleLeft |
| 74 | ThrottleRight |
| 75 | TiltMotorFrontLeft |
| 76 | TiltMotorFrontRight |
| 77 | ElevonLeft |
| 78 | ElevonRight |
| 79 | VTailLeft |
| 80 | VTailRight |
| 81 | BoostThrottle |
| 82 | Motor9 |
| 83 | Motor10 |
| 84 | Motor11 |
| 85 | Motor12 |
| 86 | DifferentialSpoilerLeft2 |
| 87 | DifferentialSpoilerRight2 |
| 88 | Winch |
| 89 | Main Sail |
| 90 | CameraISO |
| 91 | CameraAperture |
| 92 | CameraFocus |
| 93 | CameraShutterSpeed |
| 94 | Script1 |
| 95 | Script2 |
| 96 | Script3 |
| 97 | Script4 |
| 98 | Script5 |
| 99 | Script6 |
| 100 | Script7 |
| 101 | Script8 |
| 102 | Script9 |
| 103 | Script10 |
| 104 | Script11 |
| 105 | Script12 |
| 106 | Script13 |
| 107 | Script14 |
| 108 | Script15 |
| 109 | Script16 |
| 120 | NeoPixel1 |
| 121 | NeoPixel2 |
| 122 | NeoPixel3 |
| 123 | NeoPixel4 |
| 124 | RateRoll |
| 125 | RatePitch |
| 126 | RateThrust |
| 127 | RateYaw |
| 128 | WingSailElevator |
| 129 | ProfiLED1 |
| 130 | ProfiLED2 |
| 131 | ProfiLED3 |
| 132 | ProfiLEDClock |
| 133 | Winch Clutch |
| 134 | SERVOn_MIN |
| 135 | SERVOn_TRIM |
| 136 | SERVOn_MAX |
| 137 | SailMastRotation |
| 138 | Alarm |
| 139 | Alarm Inverted |
| 140 | RCIN1Scaled |
| 141 | RCIN2Scaled |
| 142 | RCIN3Scaled |
| 143 | RCIN4Scaled |
| 144 | RCIN5Scaled |
| 145 | RCIN6Scaled |
| 146 | RCIN7Scaled |
| 147 | RCIN8Scaled |
| 148 | RCIN9Scaled |
| 149 | RCIN10Scaled |
| 150 | RCIN11Scaled |
| 151 | RCIN12Scaled |
| 152 | RCIN13Scaled |
| 153 | RCIN14Scaled |
| 154 | RCIN15Scaled |
| 155 | RCIN16Scaled |
| 180 | CameraZoom |
Enable of BLHeli pass-thru servo protocol support to specific channels. This mask is in addition to motors enabled using SERVO_BLH_AUTO (if any)
If set to 1 this auto-enables BLHeli pass-thru support for all multicopter motors
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
Setting SERVO_BLH_TEST to a motor number enables an internal test of the BLHeli ESC protocol to the corresponding ESC. The debug output is displayed on the USB console.
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | TestMotor1 |
| 2 | TestMotor2 |
| 3 | TestMotor3 |
| 4 | TestMotor4 |
| 5 | TestMotor5 |
| 6 | TestMotor6 |
| 7 | TestMotor7 |
| 8 | TestMotor8 |
This sets the inactivity timeout for the BLHeli protocol in seconds. If no packets are received in this time normal MAVLink operations are resumed. A value of 0 means no timeout
This sets the rate in Hz for requesting telemetry from ESCs. It is the rate per ESC. Setting to zero disables telemetry requests
When set to 1 this enabled verbose debugging output over MAVLink when the blheli protocol is active. This can be used to diagnose failures.
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Enabled |
When set to a non-zero value this overrides the output type for the output channels given by SERVO_BLH_MASK. This can be used to enable DShot on outputs that are not part of the multicopter motors group.
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | OneShot |
| 2 | OneShot125 |
| 3 | Brushed |
| 4 | DShot150 |
| 5 | DShot300 |
| 6 | DShot600 |
| 7 | DShot1200 |
This sets the mavlink channel to use for blheli pass-thru. The channel number is determined by the number of serial ports configured to use mavlink. So 0 is always the console, 1 is the next serial port using mavlink, 2 the next after that and so on.
| Value | Meaning |
|---|---|
| 0 | Console |
| 1 | Mavlink Serial Channel1 |
| 2 | Mavlink Serial Channel2 |
| 3 | Mavlink Serial Channel3 |
| 4 | Mavlink Serial Channel4 |
| 5 | Mavlink Serial Channel5 |
This allows calculation of true RPM from ESC's eRPM. The default is 14.
Mask of channels which are dynamically reversible. This is used to configure ESCs in '3D' mode, allowing for the motor to spin in either direction. Note that setting an ESC as reversible with this option on AM32 will result in the forward direction of the ESC changing. You can combine with parameter with the SERVO_BLH_RVMASK parameter to maintain the same direction when the ESC is in 3D mode as it has in unidirectional (non-3D) mode.
Mask of channels which support bi-directional dshot telemetry. This is used for ESCs which have firmware that supports bi-directional dshot allowing fast rpm telemetry values to be returned for the harmonic notch.
Mask of channels which are reversed. This is used to configure ESCs to reverse motor direction. Note that when combined with SERVO_BLH_3DMASK this will change what direction is considered to be forward.
Servo channel mask specifying FETtec ESC output.
Servo channel mask to reverse rotation of FETtec ESC outputs.
Number of motor electrical poles
Position minimum at servo min value. This should be within the position control range of the servos, normally 0 to 4095
Position maximum at servo max value. This should be within the position control range of the servos, normally 0 to 4095
This sets the SBUS output frame rate in Hz.
Enable of volz servo protocol to specific channels
Range to map between 1000 and 2000 PWM. Default value of 200 gives full +-100 deg range of extended position command. This results in 0.2 deg movement per US change in PWM. If the full range is not needed it can be reduced to increase resolution. 40 deg range gives 0.04 deg movement per US change in PWM, this is higher resolution than possible with the VOLZ protocol so further reduction in range will not improve resolution. Reduced range does allow PWMs outside the 1000 to 2000 range, with 40 deg range 750 PWM results in a angle of -30 deg, 2250 would be +30 deg. This is still limited by the 200 deg maximum range of the actuator.
Number of times board has been booted
Total FlightTime (seconds)
Total time autopilot has run
Seconds since January 1st 2016 (Unix epoch+1451606400) since statistics reset (set to 0 to reset statistics, other set values will be ignored)
Total number of flights
Enables temperature sensor logging
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | Log all instances |
| 2 | Log only instances with sensor source set to None |
Enables temperature sensors
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | TSYS01 |
| 2 | MCP9600 |
| 3 | MAX31865 2 or 4 wire |
| 4 | TSYS03 |
| 5 | Analog |
| 6 | DroneCAN |
| 7 | MLX90614 |
| 8 | SHT3x |
| 9 | MAX31865 3 wire |
Temperature sensor bus number, typically used to select from multiple I2C buses
Temperature sensor address, typically used for I2C address
Sensor Source is used to designate which device's temperature report will be replaced by this temperature sensor's data. If 0 (None) then the data is only available via log. In the future a new Motor temperature report will be created for returning data directly.
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | ESC |
| 2 | Motor |
| 3 | Battery Index |
| 4 | Battery ID/SerialNumber |
| 5 | CAN based Pitot tube |
| 6 | DroneCAN-out on AP_Periph |
Sensor Source Identification is used to replace a specific instance of a system component's temperature report with the temp sensor's. Examples: TEMP_SRC = 1 (ESC), TEMP_SRC_ID = 1 will set the temp of ESC1. TEMP_SRC = 3 (BatteryIndex),TEMP_SRC_ID = 2 will set the temp of BATT2. TEMP_SRC = 4 (BatteryId/SerialNum),TEMP_SRC_ID=42 will set the temp of all batteries that have param BATTn_SERIAL = 42.
Sets the analog input pin that should be used for temprature monitoring. Values for some autopilots are given as examples. Search wiki for "Analog pins".
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
a0 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a1 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a2 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a3 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a4 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a5 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
Sets the message device ID this backend listens for
Nominal RTD resistance used to calculate temperature, typically 100 or 1000 ohms.
Reference resistance used to calculate temperature, in ohms
Enables temperature sensors
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | TSYS01 |
| 2 | MCP9600 |
| 3 | MAX31865 2 or 4 wire |
| 4 | TSYS03 |
| 5 | Analog |
| 6 | DroneCAN |
| 7 | MLX90614 |
| 8 | SHT3x |
| 9 | MAX31865 3 wire |
Temperature sensor bus number, typically used to select from multiple I2C buses
Temperature sensor address, typically used for I2C address
Sensor Source is used to designate which device's temperature report will be replaced by this temperature sensor's data. If 0 (None) then the data is only available via log. In the future a new Motor temperature report will be created for returning data directly.
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | ESC |
| 2 | Motor |
| 3 | Battery Index |
| 4 | Battery ID/SerialNumber |
| 5 | CAN based Pitot tube |
| 6 | DroneCAN-out on AP_Periph |
Sensor Source Identification is used to replace a specific instance of a system component's temperature report with the temp sensor's. Examples: TEMP_SRC = 1 (ESC), TEMP_SRC_ID = 1 will set the temp of ESC1. TEMP_SRC = 3 (BatteryIndex),TEMP_SRC_ID = 2 will set the temp of BATT2. TEMP_SRC = 4 (BatteryId/SerialNum),TEMP_SRC_ID=42 will set the temp of all batteries that have param BATTn_SERIAL = 42.
Sets the analog input pin that should be used for temprature monitoring. Values for some autopilots are given as examples. Search wiki for "Analog pins".
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
a0 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a1 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a2 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a3 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a4 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a5 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
Sets the message device ID this backend listens for
Nominal RTD resistance used to calculate temperature, typically 100 or 1000 ohms.
Reference resistance used to calculate temperature, in ohms
Enables temperature sensors
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | TSYS01 |
| 2 | MCP9600 |
| 3 | MAX31865 2 or 4 wire |
| 4 | TSYS03 |
| 5 | Analog |
| 6 | DroneCAN |
| 7 | MLX90614 |
| 8 | SHT3x |
| 9 | MAX31865 3 wire |
Temperature sensor bus number, typically used to select from multiple I2C buses
Temperature sensor address, typically used for I2C address
Sensor Source is used to designate which device's temperature report will be replaced by this temperature sensor's data. If 0 (None) then the data is only available via log. In the future a new Motor temperature report will be created for returning data directly.
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | ESC |
| 2 | Motor |
| 3 | Battery Index |
| 4 | Battery ID/SerialNumber |
| 5 | CAN based Pitot tube |
| 6 | DroneCAN-out on AP_Periph |
Sensor Source Identification is used to replace a specific instance of a system component's temperature report with the temp sensor's. Examples: TEMP_SRC = 1 (ESC), TEMP_SRC_ID = 1 will set the temp of ESC1. TEMP_SRC = 3 (BatteryIndex),TEMP_SRC_ID = 2 will set the temp of BATT2. TEMP_SRC = 4 (BatteryId/SerialNum),TEMP_SRC_ID=42 will set the temp of all batteries that have param BATTn_SERIAL = 42.
Sets the analog input pin that should be used for temprature monitoring. Values for some autopilots are given as examples. Search wiki for "Analog pins".
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
a0 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a1 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a2 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a3 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a4 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a5 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
Sets the message device ID this backend listens for
Nominal RTD resistance used to calculate temperature, typically 100 or 1000 ohms.
Reference resistance used to calculate temperature, in ohms
Enables temperature sensors
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | TSYS01 |
| 2 | MCP9600 |
| 3 | MAX31865 2 or 4 wire |
| 4 | TSYS03 |
| 5 | Analog |
| 6 | DroneCAN |
| 7 | MLX90614 |
| 8 | SHT3x |
| 9 | MAX31865 3 wire |
Temperature sensor bus number, typically used to select from multiple I2C buses
Temperature sensor address, typically used for I2C address
Sensor Source is used to designate which device's temperature report will be replaced by this temperature sensor's data. If 0 (None) then the data is only available via log. In the future a new Motor temperature report will be created for returning data directly.
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | ESC |
| 2 | Motor |
| 3 | Battery Index |
| 4 | Battery ID/SerialNumber |
| 5 | CAN based Pitot tube |
| 6 | DroneCAN-out on AP_Periph |
Sensor Source Identification is used to replace a specific instance of a system component's temperature report with the temp sensor's. Examples: TEMP_SRC = 1 (ESC), TEMP_SRC_ID = 1 will set the temp of ESC1. TEMP_SRC = 3 (BatteryIndex),TEMP_SRC_ID = 2 will set the temp of BATT2. TEMP_SRC = 4 (BatteryId/SerialNum),TEMP_SRC_ID=42 will set the temp of all batteries that have param BATTn_SERIAL = 42.
Sets the analog input pin that should be used for temprature monitoring. Values for some autopilots are given as examples. Search wiki for "Analog pins".
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
a0 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a1 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a2 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a3 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a4 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a5 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
Sets the message device ID this backend listens for
Nominal RTD resistance used to calculate temperature, typically 100 or 1000 ohms.
Reference resistance used to calculate temperature, in ohms
Enables temperature sensors
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | TSYS01 |
| 2 | MCP9600 |
| 3 | MAX31865 2 or 4 wire |
| 4 | TSYS03 |
| 5 | Analog |
| 6 | DroneCAN |
| 7 | MLX90614 |
| 8 | SHT3x |
| 9 | MAX31865 3 wire |
Temperature sensor bus number, typically used to select from multiple I2C buses
Temperature sensor address, typically used for I2C address
Sensor Source is used to designate which device's temperature report will be replaced by this temperature sensor's data. If 0 (None) then the data is only available via log. In the future a new Motor temperature report will be created for returning data directly.
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | ESC |
| 2 | Motor |
| 3 | Battery Index |
| 4 | Battery ID/SerialNumber |
| 5 | CAN based Pitot tube |
| 6 | DroneCAN-out on AP_Periph |
Sensor Source Identification is used to replace a specific instance of a system component's temperature report with the temp sensor's. Examples: TEMP_SRC = 1 (ESC), TEMP_SRC_ID = 1 will set the temp of ESC1. TEMP_SRC = 3 (BatteryIndex),TEMP_SRC_ID = 2 will set the temp of BATT2. TEMP_SRC = 4 (BatteryId/SerialNum),TEMP_SRC_ID=42 will set the temp of all batteries that have param BATTn_SERIAL = 42.
Sets the analog input pin that should be used for temprature monitoring. Values for some autopilots are given as examples. Search wiki for "Analog pins".
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
a0 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a1 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a2 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a3 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a4 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a5 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
Sets the message device ID this backend listens for
Nominal RTD resistance used to calculate temperature, typically 100 or 1000 ohms.
Reference resistance used to calculate temperature, in ohms
Enables temperature sensors
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | TSYS01 |
| 2 | MCP9600 |
| 3 | MAX31865 2 or 4 wire |
| 4 | TSYS03 |
| 5 | Analog |
| 6 | DroneCAN |
| 7 | MLX90614 |
| 8 | SHT3x |
| 9 | MAX31865 3 wire |
Temperature sensor bus number, typically used to select from multiple I2C buses
Temperature sensor address, typically used for I2C address
Sensor Source is used to designate which device's temperature report will be replaced by this temperature sensor's data. If 0 (None) then the data is only available via log. In the future a new Motor temperature report will be created for returning data directly.
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | ESC |
| 2 | Motor |
| 3 | Battery Index |
| 4 | Battery ID/SerialNumber |
| 5 | CAN based Pitot tube |
| 6 | DroneCAN-out on AP_Periph |
Sensor Source Identification is used to replace a specific instance of a system component's temperature report with the temp sensor's. Examples: TEMP_SRC = 1 (ESC), TEMP_SRC_ID = 1 will set the temp of ESC1. TEMP_SRC = 3 (BatteryIndex),TEMP_SRC_ID = 2 will set the temp of BATT2. TEMP_SRC = 4 (BatteryId/SerialNum),TEMP_SRC_ID=42 will set the temp of all batteries that have param BATTn_SERIAL = 42.
Sets the analog input pin that should be used for temprature monitoring. Values for some autopilots are given as examples. Search wiki for "Analog pins".
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
a0 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a1 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a2 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a3 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a4 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a5 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
Sets the message device ID this backend listens for
Nominal RTD resistance used to calculate temperature, typically 100 or 1000 ohms.
Reference resistance used to calculate temperature, in ohms
Enables temperature sensors
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | TSYS01 |
| 2 | MCP9600 |
| 3 | MAX31865 2 or 4 wire |
| 4 | TSYS03 |
| 5 | Analog |
| 6 | DroneCAN |
| 7 | MLX90614 |
| 8 | SHT3x |
| 9 | MAX31865 3 wire |
Temperature sensor bus number, typically used to select from multiple I2C buses
Temperature sensor address, typically used for I2C address
Sensor Source is used to designate which device's temperature report will be replaced by this temperature sensor's data. If 0 (None) then the data is only available via log. In the future a new Motor temperature report will be created for returning data directly.
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | ESC |
| 2 | Motor |
| 3 | Battery Index |
| 4 | Battery ID/SerialNumber |
| 5 | CAN based Pitot tube |
| 6 | DroneCAN-out on AP_Periph |
Sensor Source Identification is used to replace a specific instance of a system component's temperature report with the temp sensor's. Examples: TEMP_SRC = 1 (ESC), TEMP_SRC_ID = 1 will set the temp of ESC1. TEMP_SRC = 3 (BatteryIndex),TEMP_SRC_ID = 2 will set the temp of BATT2. TEMP_SRC = 4 (BatteryId/SerialNum),TEMP_SRC_ID=42 will set the temp of all batteries that have param BATTn_SERIAL = 42.
Sets the analog input pin that should be used for temprature monitoring. Values for some autopilots are given as examples. Search wiki for "Analog pins".
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
a0 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a1 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a2 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a3 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a4 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a5 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
Sets the message device ID this backend listens for
Nominal RTD resistance used to calculate temperature, typically 100 or 1000 ohms.
Reference resistance used to calculate temperature, in ohms
Enables temperature sensors
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | TSYS01 |
| 2 | MCP9600 |
| 3 | MAX31865 2 or 4 wire |
| 4 | TSYS03 |
| 5 | Analog |
| 6 | DroneCAN |
| 7 | MLX90614 |
| 8 | SHT3x |
| 9 | MAX31865 3 wire |
Temperature sensor bus number, typically used to select from multiple I2C buses
Temperature sensor address, typically used for I2C address
Sensor Source is used to designate which device's temperature report will be replaced by this temperature sensor's data. If 0 (None) then the data is only available via log. In the future a new Motor temperature report will be created for returning data directly.
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | ESC |
| 2 | Motor |
| 3 | Battery Index |
| 4 | Battery ID/SerialNumber |
| 5 | CAN based Pitot tube |
| 6 | DroneCAN-out on AP_Periph |
Sensor Source Identification is used to replace a specific instance of a system component's temperature report with the temp sensor's. Examples: TEMP_SRC = 1 (ESC), TEMP_SRC_ID = 1 will set the temp of ESC1. TEMP_SRC = 3 (BatteryIndex),TEMP_SRC_ID = 2 will set the temp of BATT2. TEMP_SRC = 4 (BatteryId/SerialNum),TEMP_SRC_ID=42 will set the temp of all batteries that have param BATTn_SERIAL = 42.
Sets the analog input pin that should be used for temprature monitoring. Values for some autopilots are given as examples. Search wiki for "Analog pins".
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
a0 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a1 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a2 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a3 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a4 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a5 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
Sets the message device ID this backend listens for
Nominal RTD resistance used to calculate temperature, typically 100 or 1000 ohms.
Reference resistance used to calculate temperature, in ohms
Enables temperature sensors
| Value | Meaning |
|---|---|
| 0 | Disabled |
| 1 | TSYS01 |
| 2 | MCP9600 |
| 3 | MAX31865 2 or 4 wire |
| 4 | TSYS03 |
| 5 | Analog |
| 6 | DroneCAN |
| 7 | MLX90614 |
| 8 | SHT3x |
| 9 | MAX31865 3 wire |
Temperature sensor bus number, typically used to select from multiple I2C buses
Temperature sensor address, typically used for I2C address
Sensor Source is used to designate which device's temperature report will be replaced by this temperature sensor's data. If 0 (None) then the data is only available via log. In the future a new Motor temperature report will be created for returning data directly.
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | ESC |
| 2 | Motor |
| 3 | Battery Index |
| 4 | Battery ID/SerialNumber |
| 5 | CAN based Pitot tube |
| 6 | DroneCAN-out on AP_Periph |
Sensor Source Identification is used to replace a specific instance of a system component's temperature report with the temp sensor's. Examples: TEMP_SRC = 1 (ESC), TEMP_SRC_ID = 1 will set the temp of ESC1. TEMP_SRC = 3 (BatteryIndex),TEMP_SRC_ID = 2 will set the temp of BATT2. TEMP_SRC = 4 (BatteryId/SerialNum),TEMP_SRC_ID=42 will set the temp of all batteries that have param BATTn_SERIAL = 42.
Sets the analog input pin that should be used for temprature monitoring. Values for some autopilots are given as examples. Search wiki for "Analog pins".
| Value | Meaning |
|---|---|
| -1 | Disabled |
| 2 | Pixhawk/Pixracer/Navio2/Pixhawk2_PM1 |
| 5 | Navigator |
| 13 | Pixhawk2_PM2/CubeOrange_PM2 |
| 14 | CubeOrange |
| 16 | Durandal |
| 100 | PX4-v1 |
a0 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a1 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a2 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a3 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a4 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
a5 in polynomial of form temperature in deg = a0 + a1*voltage + a2*voltage^2 + a3*voltage^3 + a4*voltage^4 + a5*voltage^5
Sets the message device ID this backend listens for
Nominal RTD resistance used to calculate temperature, typically 100 or 1000 ohms.
Reference resistance used to calculate temperature, in ohms
Visual odometry camera connection type
| Value | Meaning |
|---|---|
| 0 | None |
| 1 | MAVLink |
| 2 | IntelT265 |
| 3 | VOXL(ModalAI) |
X position of the camera in body frame. Positive X is forward of the origin.
Y position of the camera in body frame. Positive Y is to the right of the origin.
Z position of the camera in body frame. Positive Z is down from the origin.
Visual odometery camera orientation
| Value | Meaning |
|---|---|
| 0 | Forward |
| 2 | Right |
| 4 | Back |
| 6 | Left |
| 24 | Up |
| 25 | Down |
Visual odometry scaling factor applied to position estimates from sensor
Visual odometry sensor delay relative to inertial measurements
Visual odometry velocity measurement noise in m/s
Visual odometry position measurement noise minimum (meters). This value will be used if the sensor provides a lower noise value (or no noise value)
Visual odometry yaw measurement noise minimum (radians), This value will be used if the sensor provides a lower noise value (or no noise value)
Visual odometry will only be sent to EKF if over this value. -1 to always send (even bad values), 0 to send if good or unknown
Toggles the Video Transmitter on and off
| Value | Meaning |
|---|---|
| 0 | Disable |
| 1 | Enable |
Video Transmitter Power Level. Different VTXs support different power levels, the power level chosen will be rounded down to the nearest supported power level
Video Transmitter Channel
Video Transmitter Band
| Value | Meaning |
|---|---|
| 0 | Band A |
| 1 | Band B |
| 2 | Band E |
| 3 | Airwave |
| 4 | RaceBand |
| 5 | Low RaceBand |
| 6 | 1G3 Band A |
| 7 | 1G3 Band B |
| 8 | Band X |
| 9 | 3G3 Band A |
| 10 | 3G3 Band B |
Video Transmitter Frequency. The frequency is derived from the setting of BAND and CHANNEL
Video Transmitter Options. Pitmode puts the VTX in a low power state. Unlocked enables certain restricted frequencies and power levels. Do not enable the Unlocked option unless you have appropriate permissions in your jurisdiction to transmit at high power levels. One stop-bit may be required for VTXs that erroneously mimic iNav behaviour.
Video Transmitter Maximum Power Level. Different VTXs support different power levels, this prevents the power aux switch from requesting too high a power level. The switch supports 6 power levels and the selected power will be a subdivision between 0 and this setting.