Complete Parameter List

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.

Rover Parameters

Eeprom format version number (Rover:FORMAT_VERSION)

This value is incremented when changes are made to the eeprom format

Log bitmask (Rover:LOG_BITMASK)

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.

• Bitmask: 0:Fast Attitude,1:Medium Attitude,2:GPS,3:System Performance,4:Throttle,5:Navigation Tuning,7:IMU,8:Mission Commands,9:Battery Monitor,10:Rangefinder,11:Compass,12:Camera,13:Steering,14:RC Input-Output,19:Raw IMU,20:Video Stabilization,21:Optical Flow

Reset Switch Channel (Rover:RST_SWITCH_CH)

RC channel to use to reset to last flight mode after geofence takeover.

Initial driving mode (Rover:INITIAL_MODE)

This selects the mode to start in on boot. This is useful for when you want to start in AUTO mode on boot without a receiver. Usually used in combination with when AUTO_TRIGGER_PIN or AUTO_KICKSTART.

Value	Meaning
0	Manual
1	Acro
3	Steering
4	Hold
5	Loiter
6	Follow
7	Simple
8	Dock
9	Circle
10	Auto
11	RTL
12	SmartRTL
15	Guided

MAVLink system ID of this vehicle (Rover:SYSID_THISMAV)

Allows setting an individual MAVLink system id for this vehicle to distinguish it from others on the same network

• Range: 1 255

MAVLink ground station ID (Rover:SYSID_MYGCS)

The identifier of the ground station in the MAVLink protocol. Don't change this unless you also modify the ground station to match.

• Range: 1 255

Telemetry startup delay (Rover:TELEM_DELAY)

The amount of time (in seconds) to delay radio telemetry to prevent an Xbee bricking on power up

• Units: seconds
• Range: 0 30
• Increment: 1

GCS PID tuning mask (Rover:GCS_PID_MASK)

bitmask of PIDs to send MAVLink PID_TUNING messages for

Value	Meaning
0	None
1	Steering
2	Throttle
4	Pitch
8	Left Wheel
16	Right Wheel
32	Sailboat Heel
64	Velocity North
128	Velocity East

• Bitmask: 0:Steering,1:Throttle,2:Pitch,3:Left Wheel,4:Right Wheel,5:Sailboat Heel,6:Velocity North,7:Velocity East

Auto mode trigger pin (Rover:AUTO_TRIGGER_PIN)

pin number to use to enable the throttle in auto mode. If set to -1 then don't use a trigger, otherwise this is a pin number which if held low in auto mode will enable the motor to run. If the switch is released while in AUTO then the motor will stop again. This can be used in combination with INITIAL_MODE to give a 'press button to start' rover with no receiver.

Value	Meaning
-1	Disabled
0	APM TriggerPin0
1	APM TriggerPin1
2	APM TriggerPin2
3	APM TriggerPin3
4	APM TriggerPin4
5	APM TriggerPin5
6	APM TriggerPin6
7	APM TriggerPin7
8	APM TriggerPin8
50	AUX1
51	AUX2
52	AUX3
53	AUX4
54	AUX5
55	AUX6

Auto mode trigger kickstart acceleration (Rover:AUTO_KICKSTART)

X acceleration in meters/second/second to use to trigger the motor start in auto mode. If set to zero then auto throttle starts immediately when the mode switch happens, otherwise the rover waits for the X acceleration to go above this value before it will start the motor

• Units: meters per square second
• Range: 0 20
• Increment: 0.1

Target cruise speed in auto modes (Rover:CRUISE_SPEED)

The target speed in auto missions.

• Units: meters per second
• Range: 0 100
• Increment: 0.1

Base throttle percentage in auto (Rover:CRUISE_THROTTLE)

The base throttle percentage to use in auto mode. The CRUISE_SPEED parameter controls the target speed, but the rover starts with the CRUISE_THROTTLE setting as the initial estimate for how much throttle is needed to achieve that speed. It then adjusts the throttle based on how fast the rover is actually going.

• Units: percent
• Range: 0 100
• Increment: 1

Pilot input steering type (Rover:PILOT_STEER_TYPE)

Pilot RC input interpretation

Value	Meaning
0	Default
1	Two Paddles Input
2	Direction reversed when backing up
3	Direction unchanged when backing up

Failsafe Action (Rover:FS_ACTION)

What to do on a failsafe event

Value	Meaning
0	Nothing
1	RTL
2	Hold
3	SmartRTL or RTL
4	SmartRTL or Hold

Failsafe timeout (Rover:FS_TIMEOUT)

The time in seconds that a failsafe condition must persist before the failsafe action is triggered

• Units: seconds
• Range: 1 100
• Increment: 0.5

Throttle Failsafe Enable (Rover:FS_THR_ENABLE)

The throttle failsafe allows you to configure a software failsafe activated by a setting on the throttle input channel to a low value. This can be used to detect the RC transmitter going out of range. Failsafe will be triggered when the throttle channel goes below the FS_THR_VALUE for FS_TIMEOUT seconds.

Value	Meaning
0	Disabled
1	Enabled
2	Enabled Continue with Mission in Auto

Throttle Failsafe Value (Rover:FS_THR_VALUE)

The PWM level on the throttle channel below which throttle failsafe triggers.

• Range: 910 1100
• Increment: 1

GCS failsafe enable (Rover:FS_GCS_ENABLE)

Enable ground control station telemetry failsafe. When enabled the Rover will execute the FS_ACTION when it fails to receive MAVLink heartbeat packets for FS_TIMEOUT seconds.

Value	Meaning
0	Disabled
1	Enabled
2	Enabled Continue with Mission in Auto

Crash check action (Rover:FS_CRASH_CHECK)

What to do on a crash event. When enabled the rover will go to hold if a crash is detected.

Value	Meaning
0	Disabled
1	Hold
2	HoldAndDisarm

EKF Failsafe Action (Rover:FS_EKF_ACTION)

Controls the action that will be taken when an EKF failsafe is invoked

Value	Meaning
0	Disabled
1	Hold
2	ReportOnly

EKF failsafe variance threshold (Rover:FS_EKF_THRESH)

Allows setting the maximum acceptable compass and velocity variance

Value	Meaning
0.6	Strict
0.8	Default
1.0	Relaxed

Mode channel (Rover:MODE_CH)

RC Channel to use for driving mode control

Mode1 (Rover:MODE1)

Driving mode for switch position 1 (910 to 1230 and above 2049)

Value	Meaning
0	Manual
1	Acro
3	Steering
4	Hold
5	Loiter
6	Follow
7	Simple
8	Dock
9	Circle
10	Auto
11	RTL
12	SmartRTL
15	Guided

Mode2 (Rover:MODE2)

Driving mode for switch position 2 (1231 to 1360)

Value	Meaning
0	Manual
1	Acro
3	Steering
4	Hold
5	Loiter
6	Follow
7	Simple
8	Dock
9	Circle
10	Auto
11	RTL
12	SmartRTL
15	Guided

Mode3 (Rover:MODE3)

Driving mode for switch position 3 (1361 to 1490)

Value	Meaning
0	Manual
1	Acro
3	Steering
4	Hold
5	Loiter
6	Follow
7	Simple
8	Dock
9	Circle
10	Auto
11	RTL
12	SmartRTL
15	Guided

Mode4 (Rover:MODE4)

Driving mode for switch position 4 (1491 to 1620)

Value	Meaning
0	Manual
1	Acro
3	Steering
4	Hold
5	Loiter
6	Follow
7	Simple
8	Dock
9	Circle
10	Auto
11	RTL
12	SmartRTL
15	Guided

Mode5 (Rover:MODE5)

Driving mode for switch position 5 (1621 to 1749)

Value	Meaning
0	Manual
1	Acro
3	Steering
4	Hold
5	Loiter
6	Follow
7	Simple
8	Dock
9	Circle
10	Auto
11	RTL
12	SmartRTL
15	Guided

Mode6 (Rover:MODE6)

Driving mode for switch position 6 (1750 to 2049)

Value	Meaning
0	Manual
1	Acro
3	Steering
4	Hold
5	Loiter
6	Follow
7	Simple
8	Dock
9	Circle
10	Auto
11	RTL
12	SmartRTL
15	Guided

GCS sysid enforcement (Rover:SYSID_ENFORCE)

This controls whether packets from other than the expected GCS system ID will be accepted

Value	Meaning
0	NotEnforced
1	Enforced

Turn radius of vehicle (Rover:TURN_RADIUS)

Turn radius of vehicle in meters while at low speeds. Lower values produce tighter turns in steering mode

• Units: meters
• Range: 0 10
• Increment: 0.1

Acro mode turn rate maximum (Rover:ACRO_TURN_RATE)

Acro mode turn rate maximum

• Units: degrees per second
• Range: 0 360
• Increment: 1

Return-to-Launch speed default (Rover:RTL_SPEED)

Return-to-Launch speed default. If zero use WP_SPEED or CRUISE_SPEED.

• Units: meters per second
• Range: 0 100
• Increment: 0.1

Frame Class (Rover:FRAME_CLASS)

Frame Class

Value	Meaning
0	Undefined
1	Rover
2	Boat
3	BalanceBot

BalanceBot Maximum Pitch (Rover:BAL_PITCH_MAX)

Pitch angle in degrees at 100% throttle

• Units: degrees
• Range: 0 15
• Increment: 0.1

Crash Angle (Rover:CRASH_ANGLE)

Pitch/Roll angle limit in degrees for crash check. Zero disables check

• Units: degrees
• Range: 0 60
• Increment: 1

Frame Type (Rover:FRAME_TYPE)

Frame Type

Value	Meaning
0	Undefined
1	Omni3
2	OmniX
3	OmniPlus

• RebootRequired: True

Loiter type (Rover:LOIT_TYPE)

Loiter behaviour when moving to the target point

Value	Meaning
0	Forward or reverse to target point
1	Always face bow towards target point
2	Always face stern towards target point

Simple_Type (Rover:SIMPLE_TYPE)

Simple mode types

Value	Meaning
0	InitialHeading
1	CardinalDirections

• RebootRequired: True

Loiter radius (Rover:LOIT_RADIUS)

Vehicle will drift when within this distance of the target position

• Units: meters
• Range: 0 20
• Increment: 1

Mission done behave (Rover:MIS_DONE_BEHAVE)

Behaviour after mission completes

Value	Meaning
0	Hold in Auto Mode
1	Loiter in Auto Mode
2	Acro Mode
3	Manual Mode

Balance Bot pitch trim angle (Rover:BAL_PITCH_TRIM)

Balance Bot pitch trim for balancing. This offsets the tilt of the center of mass.

• Units: degrees
• Range: -2 2
• Increment: 0.1

Stick Mixing (Rover:STICK_MIXING)

When enabled, this adds steering user stick input in auto modes, allowing the user to have some degree of control without changing modes.

Value	Meaning
0	Disabled
1	Enabled

Speed maximum (Rover:SPEED_MAX)

Maximum speed vehicle can obtain at full throttle. If 0, it will be estimated based on CRUISE_SPEED and CRUISE_THROTTLE.

• Units: meters per second
• Range: 0 30
• Increment: 0.1

Loiter speed gain (Rover:LOIT_SPEED_GAIN)

Determines how agressively LOITER tries to correct for drift from loiter point. Higher is faster but default should be acceptable.

• Range: 0 5
• Increment: 0.01

Failsafe Options (Rover:FS_OPTIONS)

Bitmask to enable failsafe options

Value	Meaning
0	None
1	Failsafe enabled in Hold mode

• Bitmask: 0:Failsafe enabled in Hold mode

Guided mode options (Rover:GUID_OPTIONS)

Options that can be applied to change guided mode behaviour

• Bitmask: 6:SCurves used for navigation

Manual mode options (Rover:MANUAL_OPTIONS)

Manual mode specific options

• Bitmask: 0:Enable steering speed scaling

Manual Steering Expo (Rover:MANUAL_STR_EXPO)

Manual steering expo to allow faster steering when stick at edges

Value	Meaning
0	Disabled
0.1	Very Low
0.2	Low
0.3	Medium
0.4	High
0.5	Very High

• Range: -0.5 0.95

GCS failsafe timeout (Rover:FS_GCS_TIMEOUT)

Timeout before triggering the GCS failsafe

• Units: seconds
• Range: 2 120
• Increment: 1

Channel 7 option (Rover:CH7_OPTION)

What to do use channel 7 for

Value	Meaning
0	Nothing
1	SaveWaypoint
2	LearnCruiseSpeed
3	ArmDisarm
4	Manual
5	Acro
6	Steering
7	Hold
8	Auto
9	RTL
10	SmartRTL
11	Guided
12	Loiter

Auxiliary switch channel (Rover:AUX_CH)

RC Channel to use for auxiliary functions including saving waypoints

Pivot turn angle (Rover:PIVOT_TURN_ANGLE)

Navigation angle threshold in degrees to switch to pivot steering. This allows you to setup a skid steering rover to turn on the spot in auto mode when the angle it needs to turn it greater than this angle. An angle of zero means to disable pivot turning. Note that you will probably also want to set a low value for WP_RADIUS to get neat turns.

• Units: degrees
• Range: 0 360
• Increment: 1

Pivot turn rate (Rover:PIVOT_TURN_RATE)

Desired pivot turn rate in deg/s.

• Units: degrees per second
• Range: 0 360
• Increment: 1

Lua Script Parameters

Ship landing enable (SHIP_ENABLE)

Enable ship landing system

Value	Meaning
0	Disabled
1	Enabled

Ship landing angle (SHIP_LAND_ANGLE)

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.

• Range: -180 180
• Units: degrees

Ship automatic offset trigger (SHIP_AUTO_OFS)

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

Quicktune enable (QUIK_ENABLE)

Enable quicktune system

Value	Meaning
0	Disabled
1	Enabled

Quicktune axes (QUIK_AXES)

axes to tune

• Bitmask: 0:Roll,1:Pitch,2:Yaw

Quicktune doubling time (QUIK_DOUBLE_TIME)

Time to double a tuning parameter. Raise this for a slower tune.

• Range: 5 20
• Units: seconds

Quicktune gain margin (QUIK_GAIN_MARGIN)

Reduction in gain after oscillation detected. Raise this number to get a more conservative tune

• Range: 20 80
• Units: percent

Quicktune oscillation rate threshold (QUIK_OSC_SMAX)

Threshold for oscillation detection. A lower value will lead to a more conservative tune.

• Range: 1 10

Quicktune Yaw P max (QUIK_YAW_P_MAX)

Maximum value for yaw P gain

• Range: 0.1 3

Quicktune Yaw D max (QUIK_YAW_D_MAX)

Maximum value for yaw D gain

• Range: 0.001 1

Quicktune roll/pitch PI ratio (QUIK_RP_PI_RATIO)

Ratio between P and I gains for roll and pitch. Raise this to get a lower I gain

• Range: 0.5 1.0

Quicktune Yaw PI ratio (QUIK_Y_PI_RATIO)

Ratio between P and I gains for yaw. Raise this to get a lower I gain

• Range: 0.5 20

Quicktune auto filter enable (QUIK_AUTO_FILTER)

When enabled the PID filter settings are automatically set based on INS_GYRO_FILTER

Value	Meaning
0	Disabled
1	Enabled

Quicktune auto save (QUIK_AUTO_SAVE)

Number of seconds after completion of tune to auto-save. This is useful when using a 2 position switch for quicktune

• Units: seconds

Quicktune RC function (QUIK_RC_FUNC)

RCn_OPTION number to use to control tuning stop/start/save

Quicktune maximum gain reduction (QUIK_MAX_REDUCE)

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.

• Units: percent
• Range: 0 100

Deadreckoning Enable (DR_ENABLE)

Deadreckoning Enable

Value	Meaning
0	Disabled
1	Enabled

Deadreckoning Enable Distance (DR_ENABLE_DIST)

Distance from home (in meters) beyond which the dead reckoning will be enabled

• Units: meters

Deadreckoning GPS speed accuracy maximum threshold (DR_GPS_SACC_MAX)

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

• Range: 0 10

Deadreckoning GPS satellite count min threshold (DR_GPS_SAT_MIN)

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

• Range: 0 30

Deadreckoning GPS check trigger seconds (DR_GPS_TRIGG_SEC)

GPS checks must fail for this many seconds before dead reckoning will be triggered

• Units: seconds

Deadreckoning Lean Angle (DR_FLY_ANGLE)

lean angle (in degrees) during deadreckoning

• Units: degrees
• Range: 0 45

Deadreckoning Altitude Min (DR_FLY_ALT_MIN)

Copter will fly at at least this altitude (in meters) above home during deadreckoning

• Units: meters
• Range: 0 1000

Deadreckoning flight timeout (DR_FLY_TIMEOUT)

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

• Units: seconds

Deadreckoning Next Mode (DR_NEXT_MODE)

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

Force enable High Latency mode (RCK_FORCEHL)

Automatically enables High Latency mode if not already enabled

Value	Meaning
0	Disabled
1	Enabled

Update rate (RCK_PERIOD)

When in High Latency mode, send Rockblock updates every N seconds

• Range: 0 600
• Units: seconds

Display Rockblock debugging text (RCK_DEBUG)

Sends Rockblock debug text to GCS via statustexts

Value	Meaning
0	Disabled
1	Enabled

Enable Message transmission (RCK_ENABLE)

Enables the Rockblock sending and recieving

Value	Meaning
0	Disabled
1	Enabled

Rover Quicktune enable (RTUN_ENABLE)

Enable quicktune system

Value	Meaning
0	Disabled
1	Enabled

Rover Quicktune axes (RTUN_AXES)

axes to tune

• Bitmask: 0:Steering,1:Speed

Rover Quicktune Steering Rate FeedForward ratio (RTUN_STR_FFRATIO)

Ratio between measured response and FF gain. Raise this to get a higher FF gain

• Range: 0 1.0

Rover Quicktune Steering FF to P ratio (RTUN_STR_P_RATIO)

Ratio between steering FF and P gains. Raise this to get a higher P gain, 0 to leave P unchanged

• Range: 0 2.0

Rover Quicktune Steering FF to I ratio (RTUN_STR_I_RATIO)

Ratio between steering FF and I gains. Raise this to get a higher I gain, 0 to leave I unchanged

• Range: 0 2.0

Rover Quicktune Speed FeedForward (equivalent) ratio (RTUN_SPD_FFRATIO)

Ratio between measured response and CRUISE_THROTTLE value. Raise this to get a higher CRUISE_THROTTLE value

• Range: 0 1.0

Rover Quicktune Speed FF to P ratio (RTUN_SPD_P_RATIO)

Ratio between speed FF and P gain. Raise this to get a higher P gain, 0 to leave P unchanged

• Range: 0 2.0

Rover Quicktune Speed FF to I ratio (RTUN_SPD_I_RATIO)

Ratio between speed FF and I gain. Raise this to get a higher I gain, 0 to leave I unchanged

• Range: 0 2.0

Rover Quicktune auto filter enable (RTUN_AUTO_FILTER)

When enabled the PID filter settings are automatically set based on INS_GYRO_FILTER

Value	Meaning
0	Disabled
1	Enabled

Rover Quicktune auto save (RTUN_AUTO_SAVE)

Number of seconds after completion of tune to auto-save. This is useful when using a 2 position switch for quicktune

• Units: seconds

Rover Quicktune RC function (RTUN_RC_FUNC)

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

DJIRS2 debug (DJIR_DEBUG)

Enable DJIRS2 debug

Value	Meaning
0	Disabled
1	Enabled
2	Enabled with attitude reporting

DJIRS2 upside down (DJIR_UPSIDEDOWN)

DJIRS2 upside down

Value	Meaning
0	Right side up
1	Upside down

Enable SkyPower EFI support (EFI_SP_ENABLE)

Enable SkyPower EFI support

Value	Meaning
0	Disabled
1	Enabled

Set SkyPower EFI CAN driver (EFI_SP_CANDRV)

Set SkyPower EFI CAN driver

Value	Meaning
0	None
1	1stCANDriver
2	2ndCanDriver

SkyPower EFI update rate (EFI_SP_UPDATE_HZ)

SkyPower EFI update rate

• Range: 10 200
• Units: hertz

SkyPower EFI throttle function (EFI_SP_THR_FN)

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 (EFI_SP_THR_RATE)

SkyPower EFI throttle rate. This sets rate at which throttle updates are sent to the engine

• Range: 10 100
• Units: hertz

SkyPower EFI start function (EFI_SP_START_FN)

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 (EFI_SP_GEN_FN)

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 (EFI_SP_MIN_RPM)

SkyPower EFI minimum RPM. This is the RPM below which the engine is considered to be stopped

• Range: 1 1000

SkyPower EFI telemetry rate (EFI_SP_TLM_RT)

SkyPower EFI telemetry rate. This is the rate at which extra telemetry values are sent to the GCS

• Range: 1 10
• Units: hertz

SkyPower EFI log rate (EFI_SP_LOG_RT)

SkyPower EFI log rate. This is the rate at which extra logging of the SkyPower EFI is performed

• Range: 1 50
• Units: hertz

SkyPower EFI allow start disarmed (EFI_SP_ST_DISARM)

SkyPower EFI allow start disarmed. This controls if starting the engine while disarmed is allowed

Value	Meaning
0	Disabled
1	Enabled

AFS_ Parameters

Enable Advanced Failsafe (AFS_ENABLE)

This enables the advanced failsafe system. If this is set to zero (disable) then all the other AFS options have no effect

Manual Pin (AFS_MAN_PIN)

This sets a digital output pin to set high when in manual mode. See the Wiki's "GPIOs" page for how to determine the pin number for a given autopilot.

Heartbeat Pin (AFS_HB_PIN)

This sets a digital output pin which is cycled at 10Hz when termination is not activated. Note that if a FS_TERM_PIN is set then the heartbeat pin will continue to cycle at 10Hz when termination is activated, to allow the termination board to distinguish between autopilot crash and termination. 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
49	BB Blue GP0 pin 4
50	AUXOUT1
51	AUXOUT2
52	AUXOUT3
53	AUXOUT4
54	AUXOUT5
55	AUXOUT6
57	BB Blue GP0 pin 3
113	BB Blue GP0 pin 6
116	BB Blue GP0 pin 5

Comms Waypoint (AFS_WP_COMMS)

Waypoint number to navigate to on comms loss

GPS Loss Waypoint (AFS_WP_GPS_LOSS)

Waypoint number to navigate to on GPS lock loss

Force Terminate (AFS_TERMINATE)

Can be set in flight to force termination of the heartbeat signal

Terminate action (AFS_TERM_ACTION)

This can be used to force an action on flight termination. Normally this is handled by an external failsafe board, but you can setup ArduPilot to handle it here. Please consult the wiki for more information on the possible values of the parameter

Terminate Pin (AFS_TERM_PIN)

This sets a digital output pin to set high on flight termination. 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
49	BB Blue GP0 pin 4
50	AUXOUT1
51	AUXOUT2
52	AUXOUT3
53	AUXOUT4
54	AUXOUT5
55	AUXOUT6
57	BB Blue GP0 pin 3
113	BB Blue GP0 pin 6
116	BB Blue GP0 pin 5

AMSL limit (AFS_AMSL_LIMIT)

This sets the AMSL (above mean sea level) altitude limit. If the pressure altitude determined by QNH exceeds this limit then flight termination will be forced. Note that this limit is in meters, whereas pressure altitude limits are often quoted in feet. A value of zero disables the pressure altitude limit.

• Units: meters

Error margin for GPS based AMSL limit (AFS_AMSL_ERR_GPS)

This sets margin for error in GPS derived altitude limit. This error margin is only used if the barometer has failed. If the barometer fails then the GPS will be used to enforce the AMSL_LIMIT, but this margin will be subtracted from the AMSL_LIMIT first, to ensure that even with the given amount of GPS altitude error the pressure altitude is not breached. OBC users should set this to comply with their D2 safety case. A value of -1 will mean that barometer failure will lead to immediate termination.

• Units: meters

QNH pressure (AFS_QNH_PRESSURE)

This sets the QNH pressure in millibars to be used for pressure altitude in the altitude limit. A value of zero disables the altitude limit.

• Units: hectopascal

Maximum number of GPS loss events (AFS_MAX_GPS_LOSS)

Maximum number of GPS loss events before the aircraft stops returning to mission on GPS recovery. Use zero to allow for any number of GPS loss events.

Maximum number of comms loss events (AFS_MAX_COM_LOSS)

Maximum number of comms loss events before the aircraft stops returning to mission on comms recovery. Use zero to allow for any number of comms loss events.

Enable geofence Advanced Failsafe (AFS_GEOFENCE)

This enables the geofence part of the AFS. Will only be in effect if AFS_ENABLE is also 1

Enable RC Advanced Failsafe (AFS_RC)

This enables the RC part of the AFS. Will only be in effect if AFS_ENABLE is also 1

Enable RC Termination only in manual control modes (AFS_RC_MAN_ONLY)

If this parameter is set to 1, then an RC loss will only cause the plane to terminate in manual control modes. If it is 0, then the plane will terminate in any flight mode.

Enable dual loss terminate due to failure of both GCS and GPS simultaneously (AFS_DUAL_LOSS)

This enables the dual loss termination part of the AFS system. If this parameter is 1 and both GPS and the ground control station fail simultaneously, this will be considered a "dual loss" and cause termination.

RC failure time (AFS_RC_FAIL_TIME)

This is the time in seconds in manual mode that failsafe termination will activate if RC input is lost. For the OBC rules this should be (1.5). Use 0 to disable.

• Units: seconds

Max allowed range (AFS_MAX_RANGE)

This is the maximum range of the vehicle in kilometers from first arming. If the vehicle goes beyond this range then the TERM_ACTION is performed. A value of zero disables this feature.

• Units: kilometers

AHRS_ Parameters

AHRS GPS gain (AHRS_GPS_GAIN)

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.

• Range: 0.0 1.0
• Increment: .01

AHRS use GPS for DCM navigation and position-down (AHRS_GPS_USE)

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

Yaw P (AHRS_YAW_P)

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.

• Range: 0.1 0.4
• Increment: .01

AHRS RP_P (AHRS_RP_P)

This controls how fast the accelerometers correct the attitude

• Range: 0.1 0.4
• Increment: .01

Maximum wind (AHRS_WIND_MAX)

This sets the maximum allowable difference between ground speed and airspeed. This allows the plane to cope with a failing airspeed sensor. A value of zero means to use the airspeed as is. See ARSPD_OPTIONS and ARSPD_MAX_WIND to disable airspeed sensors.

• Range: 0 127
• Units: meters per second
• Increment: 1

AHRS Trim Roll (AHRS_TRIM_X)

Compensates for the roll angle difference between the control board and the frame. Positive values make the vehicle roll right.

• Units: radians
• Range: -0.1745 +0.1745
• Increment: 0.01

AHRS Trim Pitch (AHRS_TRIM_Y)

Compensates for the pitch angle difference between the control board and the frame. Positive values make the vehicle pitch up/back.

• Units: radians
• Range: -0.1745 +0.1745
• Increment: 0.01

AHRS Trim Yaw (AHRS_TRIM_Z)

Not Used

• Units: radians
• Range: -0.1745 +0.1745
• Increment: 0.01

Board Orientation (AHRS_ORIENTATION)

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

AHRS Velocity Complementary Filter Beta Coefficient (AHRS_COMP_BETA)

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.

• Range: 0.001 0.5
• Increment: .01

AHRS GPS Minimum satellites (AHRS_GPS_MINSATS)

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.

• Range: 0 10
• Increment: 1

Use NavEKF Kalman filter for attitude and position estimation (AHRS_EKF_TYPE)

This controls which NavEKF Kalman filter version is used for attitude and position estimation

Value	Meaning
0	Disabled
2	Enable EKF2
3	Enable EKF3
11	ExternalAHRS

Board orientation roll offset (AHRS_CUSTOM_ROLL)

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.

• Range: -180 180
• Units: degrees
• Increment: 1

Board orientation pitch offset (AHRS_CUSTOM_PIT)

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.

• Range: -180 180
• Units: degrees
• Increment: 1

Board orientation yaw offset (AHRS_CUSTOM_YAW)

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.

• Range: -180 180
• Units: degrees
• Increment: 1

AIS_ Parameters

AIS receiver type (AIS_TYPE)

AIS receiver type

Value	Meaning
0	None
1	NMEA AIVDM message

• RebootRequired: True

AIS vessel list size (AIS_LIST_MAX)

AIS list size of nearest vessels. Longer lists take longer to refresh with lower SRx_ADSB values.

• Range: 1 100

AIS vessel time out (AIS_TIME_OUT)

if no updates are received in this time a vessel will be removed from the list

• Units: seconds
• Range: 1 2000

AIS logging options (AIS_LOGGING)

Bitmask of AIS logging options

• Bitmask: 0:Log all AIVDM messages,1:Log only unsupported AIVDM messages,2:Log decoded messages

ARMING_ Parameters

Require Arming Motors (ARMING_REQUIRE)

Arming disabled until some requirements are met. If 0, there are no requirements (arm immediately). If 1, require rudder stick or GCS arming before arming motors and sends the minimum throttle PWM value to the throttle channel when disarmed. If 2, require rudder stick or GCS arming and send 0 PWM to throttle channel when disarmed. See the ARMING_CHECK_* parameters to see what checks are done before arming. Note, if setting this parameter to 0 a reboot is required to arm the plane. Also note, even with this parameter at 0, if ARMING_CHECK parameter is not also zero the plane may fail to arm throttle at boot due to a pre-arm check failure. On planes with ICE enabled and the throttle while disarmed option set in ICE_OPTIONS the motor will get THR_MIN when disarmed.

Value	Meaning
0	Disabled
1	minimum PWM when disarmed
2	0 PWM when disarmed

Accelerometer error threshold (ARMING_ACCTHRESH)

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.

• Units: meters per square second
• Range: 0.25 3.0

Arming with Rudder enable/disable (ARMING_RUDDER)

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

Required mission items (ARMING_MIS_ITEMS)

Bitmask of mission items that are required to be planned in order to arm the aircraft

• Bitmask: 0:Land,1:VTOL Land,2:DO_LAND_START,3:Takeoff,4:VTOL Takeoff,5:Rallypoint,6:RTL

Arm Checks to Perform (bitmask) (ARMING_CHECK)

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.

• Bitmask: 0:All,1:Barometer,2:Compass,3:GPS lock,4:INS,5:Parameters,6:RC Channels,7:Board voltage,8:Battery Level,10:Logging Available,11:Hardware safety switch,12:GPS Configuration,13:System,14:Mission,15:Rangefinder,16:Camera,17:AuxAuth,18:VisualOdometry,19:FFT

Arming options (ARMING_OPTIONS)

Options that can be applied to change arming behaviour

Value	Meaning
0	None
1	Disable prearm display

ARSPD Parameters

Airspeed Enable (ARSPD_ENABLE)

Enable airspeed sensor support

Value	Meaning
0	Disable
1	Enable

Control pitot tube order (ARSPD_TUBE_ORDER)

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

Primary airspeed sensor (ARSPD_PRIMARY)

This selects which airspeed sensor will be the primary if multiple sensors are found

Value	Meaning
0	FirstSensor
1	2ndSensor

Airspeed options bitmask (ARSPD_OPTIONS)

This parameter and function is not used by this vehicle. Always set to 0.

• Bitmask: 0:SpeedMismatchDisable, 1:AllowSpeedMismatchRecovery, 2:DisableVoltageCorrection, 3:UseEkf3Consistency

Maximum airspeed and ground speed difference (ARSPD_WIND_MAX)

This parameter and function is not used by this vehicle. Always set to 0.

• Units: meters per second

Airspeed and ground speed difference that gives a warning (ARSPD_WIND_WARN)

This parameter and function is not used by this vehicle. Always set to 0.

• Units: meters per second

Re-enable Consistency Check Gate Size (ARSPD_WIND_GATE)

This parameter and function is not used by this vehicle.

• Range: 0.0 10.0

Maximum offset cal speed error (ARSPD_OFF_PCNT)

The maximum percentage speed change in airspeed reports that is allowed due to offset changes between calibraions before a warning is issued. This potential speed error is in percent of ASPD_FBW_MIN. 0 disables. Helps warn of calibrations without pitot being covered.

• Range: 0.0 10.0
• Units: percent

ARSPD2_ Parameters

Airspeed type (ARSPD2_TYPE)

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
100	SITL

Airspeed use (ARSPD2_USE)

This parameter is not used by this vehicle. Always set to 0.

Value	Meaning
0	DoNotUse
1	Use
2	UseWhenZeroThrottle

Airspeed offset (ARSPD2_OFFSET)

Airspeed calibration offset

• Increment: 0.1

Airspeed ratio (ARSPD2_RATIO)

Calibrates pitot tube pressure to velocity. Increasing this value will indicate a higher airspeed at any given dynamic pressure.

• Increment: 0.1

Airspeed pin (ARSPD2_PIN)

The pin number that the airspeed sensor is connected to for analog sensors. Set to 15 on the Pixhawk for the analog airspeed port.

This parameter and function is not used by this vehicle. Always set to 0. (ARSPD2_AUTOCAL)

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.

Control pitot tube order (ARSPD2_TUBE_ORDR)

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

Skip airspeed offset calibration on startup (ARSPD2_SKIP_CAL)

This parameter allows you to skip airspeed offset calibration on startup, instead using the offset from the last 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	Enable

The PSI range of the device (ARSPD2_PSI_RANGE)

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

Airspeed I2C bus (ARSPD2_BUS)

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

• RebootRequired: True

Airspeed ID (ARSPD2_DEVID)

Airspeed sensor ID, taking into account its type, bus and instance

• ReadOnly: True

ARSPD_ Parameters

Airspeed type (ARSPD_TYPE)

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
100	SITL

Airspeed use (ARSPD_USE)

This parameter is not used by this vehicle. Always set to 0.

Value	Meaning
0	DoNotUse
1	Use
2	UseWhenZeroThrottle

Airspeed offset (ARSPD_OFFSET)

Airspeed calibration offset

• Increment: 0.1

Airspeed ratio (ARSPD_RATIO)

Calibrates pitot tube pressure to velocity. Increasing this value will indicate a higher airspeed at any given dynamic pressure.

• Increment: 0.1

Airspeed pin (ARSPD_PIN)

The pin number that the airspeed sensor is connected to for analog sensors. Set to 15 on the Pixhawk for the analog airspeed port.

This parameter and function is not used by this vehicle. Always set to 0. (ARSPD_AUTOCAL)

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.

Control pitot tube order (ARSPD_TUBE_ORDR)

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

Skip airspeed offset calibration on startup (ARSPD_SKIP_CAL)

This parameter allows you to skip airspeed offset calibration on startup, instead using the offset from the last 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	Enable

The PSI range of the device (ARSPD_PSI_RANGE)

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

Airspeed I2C bus (ARSPD_BUS)

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

• RebootRequired: True

Airspeed ID (ARSPD_DEVID)

Airspeed sensor ID, taking into account its type, bus and instance

• ReadOnly: True

ATC Parameters

Steering control rate P gain (ATC_STR_RAT_P)

Steering control rate P gain. Converts the turn rate error (in radians/sec) to a steering control output (in the range -1 to +1)

• Range: 0.000 2.000
• Increment: 0.001

Steering control I gain (ATC_STR_RAT_I)

Steering control I gain. Corrects long term error between the desired turn rate (in rad/s) and actual

• Range: 0.000 2.000
• Increment: 0.001

Steering control I gain maximum (ATC_STR_RAT_IMAX)

Steering control I gain maximum. Constrains the steering output (range -1 to +1) that the I term will generate

• Range: 0.000 1.000
• Increment: 0.01

Steering control D gain (ATC_STR_RAT_D)

Steering control D gain. Compensates for short-term change in desired turn rate vs actual

• Range: 0.000 0.400
• Increment: 0.001

Steering control feed forward (ATC_STR_RAT_FF)

Steering control feed forward

• Range: 0.000 3.000
• Increment: 0.001

Steering control filter frequency (ATC_STR_RAT_FILT)

Steering control input filter. Lower values reduce noise but add delay.

• Range: 0.000 100.000
• Increment: 0.1
• Units: hertz

Steering control Target filter frequency in Hz (ATC_STR_RAT_FLTT)

Target filter frequency in Hz

• Range: 0.000 100.000
• Increment: 0.1
• Units: hertz

Steering control Error filter frequency in Hz (ATC_STR_RAT_FLTE)

Error filter frequency in Hz

• Range: 0.000 100.000
• Increment: 0.1
• Units: hertz

Steering control Derivative term filter frequency in Hz (ATC_STR_RAT_FLTD)

Derivative filter frequency in Hz

• Range: 0.000 100.000
• Increment: 0.1
• Units: hertz

Steering slew rate limit (ATC_STR_RAT_SMAX)

Sets an upper limit on the slew rate produced by the combined P and D gains. If the amplitude of the control action produced by the rate feedback exceeds this value, then the D+P gain is reduced to respect the limit. This limits the amplitude of high frequency oscillations caused by an excessive gain. The limit should be set to no more than 25% of the actuators maximum slew rate to allow for load effects. Note: The gain will not be reduced to less than 10% of the nominal value. A value of zero will disable this feature.

• Range: 0 200
• Increment: 0.5

Speed control P gain (ATC_SPEED_P)

Speed control P gain. Converts the error between the desired speed (in m/s) and actual speed to a motor output (in the range -1 to +1)

• Range: 0.010 2.000
• Increment: 0.01

Speed control I gain (ATC_SPEED_I)

Speed control I gain. Corrects long term error between the desired speed (in m/s) and actual speed

• Range: 0.000 2.000
• Increment: 0.01

Speed control I gain maximum (ATC_SPEED_IMAX)

Speed control I gain maximum. Constrains the maximum motor output (range -1 to +1) that the I term will generate

• Range: 0.000 1.000
• Increment: 0.01

Speed control D gain (ATC_SPEED_D)

Speed control D gain. Compensates for short-term change in desired speed vs actual

• Range: 0.000 0.400
• Increment: 0.001

Speed control feed forward (ATC_SPEED_FF)

Speed control feed forward

• Range: 0.000 0.500
• Increment: 0.001

Speed control filter frequency (ATC_SPEED_FILT)

Speed control input filter. Lower values reduce noise but add delay.

• Range: 0.000 100.000
• Increment: 0.1
• Units: hertz

Speed control Target filter frequency in Hz (ATC_SPEED_FLTT)

Target filter frequency in Hz

• Range: 0.000 100.000
• Increment: 0.1
• Units: hertz

Speed control Error filter frequency in Hz (ATC_SPEED_FLTE)

Error filter frequency in Hz

• Range: 0.000 100.000
• Increment: 0.1
• Units: hertz

Speed control Derivative term filter frequency in Hz (ATC_SPEED_FLTD)

Derivative filter frequency in Hz

• Range: 0.000 100.000
• Increment: 0.1
• Units: hertz

Speed control slew rate limit (ATC_SPEED_SMAX)

Sets an upper limit on the slew rate produced by the combined P and D gains. If the amplitude of the control action produced by the rate feedback exceeds this value, then the D+P gain is reduced to respect the limit. This limits the amplitude of high frequency oscillations caused by an excessive gain. The limit should be set to no more than 25% of the actuators maximum slew rate to allow for load effects. Note: The gain will not be reduced to less than 10% of the nominal value. A value of zero will disable this feature.

• Range: 0 200
• Increment: 0.5

Speed control acceleration (and deceleration) maximum in m/s/s (ATC_ACCEL_MAX)

Speed control acceleration (and deceleration) maximum in m/s/s. 0 to disable acceleration limiting

• Range: 0.0 10.0
• Increment: 0.1
• Units: meters per square second

Speed control brake enable/disable (ATC_BRAKE)

Speed control brake enable/disable. Allows sending a reversed output to the motors to slow the vehicle.

Value	Meaning
0	Disable
1	Enable

Speed control stop speed (ATC_STOP_SPEED)

Speed control stop speed. Motor outputs to zero once vehicle speed falls below this value

• Range: 0.00 0.50
• Increment: 0.01
• Units: meters per second

Steering control angle P gain (ATC_STR_ANG_P)

Steering control angle P gain. Converts the error between the desired heading/yaw (in radians) and actual heading/yaw to a desired turn rate (in rad/sec)

• Range: 1.000 10.000
• Increment: 0.1

Steering control angular acceleration maximum (ATC_STR_ACC_MAX)

Steering control angular acceleration maximum (in deg/s/s). 0 to disable acceleration limiting

• Range: 0 1000
• Increment: 0.1
• Units: degrees per square second

Steering control rotation rate maximum (ATC_STR_RAT_MAX)

Steering control rotation rate maximum in deg/s. 0 to remove rate limiting

• Range: 0 1000
• Increment: 0.1
• Units: degrees per second

Speed control deceleration maximum in m/s/s (ATC_DECEL_MAX)

Speed control and deceleration maximum in m/s/s. 0 to use ATC_ACCEL_MAX for deceleration

• Range: 0.0 10.0
• Increment: 0.1
• Units: meters per square second

Pitch control P gain (ATC_BAL_P)

Pitch control P gain for BalanceBots. Converts the error between the desired pitch (in radians) and actual pitch to a motor output (in the range -1 to +1)

• Range: 0.000 2.000
• Increment: 0.01

Pitch control I gain (ATC_BAL_I)

Pitch control I gain for BalanceBots. Corrects long term error between the desired pitch (in radians) and actual pitch

• Range: 0.000 2.000
• Increment: 0.01

Pitch control I gain maximum (ATC_BAL_IMAX)

Pitch control I gain maximum. Constrains the maximum motor output (range -1 to +1) that the I term will generate

• Range: 0.000 1.000
• Increment: 0.01

Pitch control D gain (ATC_BAL_D)

Pitch control D gain. Compensates for short-term change in desired pitch vs actual

• Range: 0.000 0.100
• Increment: 0.001

Pitch control feed forward (ATC_BAL_FF)

Pitch control feed forward

• Range: 0.000 0.500
• Increment: 0.001

Pitch control filter frequency (ATC_BAL_FILT)

Pitch control input filter. Lower values reduce noise but add delay.

• Range: 0.000 100.000
• Increment: 0.1
• Units: hertz

Pitch control Target filter frequency in Hz (ATC_BAL_FLTT)

Pitch control Target filter frequency in Hz

• Range: 0.000 100.000
• Increment: 0.1
• Units: hertz

Pitch control Error filter frequency in Hz (ATC_BAL_FLTE)

Pitch control Error filter frequency in Hz

• Range: 0.000 100.000
• Increment: 0.1
• Units: hertz

Pitch control Derivative term filter frequency in Hz (ATC_BAL_FLTD)

Pitch control Derivative filter frequency in Hz

• Range: 0.000 100.000
• Increment: 0.1
• Units: hertz

Pitch control slew rate limit (ATC_BAL_SMAX)

Pitch control upper limit on the slew rate produced by the combined P and D gains. If the amplitude of the control action produced by the rate feedback exceeds this value, then the D+P gain is reduced to respect the limit. This limits the amplitude of high frequency oscillations caused by an excessive gain. The limit should be set to no more than 25% of the actuators maximum slew rate to allow for load effects. Note: The gain will not be reduced to less than 10% of the nominal value. A value of zero will disable this feature.

• Range: 0 200
• Increment: 0.5

Pitch control feed forward from current pitch angle (ATC_BAL_PIT_FF)

Pitch control feed forward from current pitch angle

• Range: 0.0 1.0
• Increment: 0.01

Sail Heel control P gain (ATC_SAIL_P)

Sail Heel control P gain for sailboats. Converts the error between the desired heel angle (in radians) and actual heel to a main sail output (in the range -1 to +1)

• Range: 0.000 2.000
• Increment: 0.01

Sail Heel control I gain (ATC_SAIL_I)

Sail Heel control I gain for sailboats. Corrects long term error between the desired heel angle (in radians) and actual

• Range: 0.000 2.000
• Increment: 0.01

Sail Heel control I gain maximum (ATC_SAIL_IMAX)

Sail Heel control I gain maximum. Constrains the maximum I term contribution to the main sail output (range -1 to +1)

• Range: 0.000 1.000
• Increment: 0.01

Sail Heel control D gain (ATC_SAIL_D)

Sail Heel control D gain. Compensates for short-term change in desired heel angle vs actual

• Range: 0.000 0.100
• Increment: 0.001

Sail Heel control feed forward (ATC_SAIL_FF)

Sail Heel control feed forward

• Range: 0.000 0.500
• Increment: 0.001

Sail Heel control filter frequency (ATC_SAIL_FILT)

Sail Heel control input filter. Lower values reduce noise but add delay.

• Range: 0.000 100.000
• Increment: 0.1
• Units: hertz

Sail Heel Target filter frequency in Hz (ATC_SAIL_FLTT)

Target filter frequency in Hz

• Range: 0.000 100.000
• Increment: 0.1
• Units: hertz

Sail Heel Error filter frequency in Hz (ATC_SAIL_FLTE)

Error filter frequency in Hz

• Range: 0.000 100.000
• Increment: 0.1
• Units: hertz

Sail Heel Derivative term filter frequency in Hz (ATC_SAIL_FLTD)

Derivative filter frequency in Hz

• Range: 0.000 100.000
• Increment: 0.1
• Units: hertz

Sail heel slew rate limit (ATC_SAIL_SMAX)

Sets an upper limit on the slew rate produced by the combined P and D gains. If the amplitude of the control action produced by the rate feedback exceeds this value, then the D+P gain is reduced to respect the limit. This limits the amplitude of high frequency oscillations caused by an excessive gain. The limit should be set to no more than 25% of the actuators maximum slew rate to allow for load effects. Note: The gain will not be reduced to less than 10% of the nominal value. A value of zero will disable this feature.

• Range: 0 200
• Increment: 0.5

Turning maximum G force (ATC_TURN_MAX_G)

The maximum turning acceleration (in units of gravities) that the rover can handle while remaining stable. The navigation code will keep the lateral acceleration below this level to avoid rolling over or slipping the wheels in turns

• Units: standard acceleration due to gravity
• Range: 0.1 10
• Increment: 0.01

Pitch control limit time constant (ATC_BAL_LIM_TC)

Pitch control limit time constant to protect against falling. Lower values limit pitch more quickly, higher values limit more slowly. Set to 0 to disable

• Range: 0.0 5.0
• Increment: 0.01

Pitch control limit throttle threshold (ATC_BAL_LIM_THR)

Pitch control limit throttle threshold. Pitch angle will be limited if throttle crosses this threshold (from 0 to 1)

• Range: 0.0 1.0
• Increment: 0.01

AVOID_ Parameters

Avoidance control enable/disable (AVOID_ENABLE)

Enabled/disable avoidance input sources

• Bitmask: 0:UseFence,1:UseProximitySensor,2:UseBeaconFence

Avoidance distance margin in GPS modes (AVOID_MARGIN)

Vehicle will attempt to stay at least this distance (in meters) from objects while in GPS modes

• Units: meters
• Range: 1 10

Avoidance behaviour (AVOID_BEHAVE)

Avoidance behaviour (slide or stop)

Value	Meaning
0	Slide
1	Stop

Avoidance maximum backup speed (AVOID_BACKUP_SPD)

Maximum speed that will be used to back away from obstacles in GPS modes (m/s). Set zero to disable

• Units: meters per second
• Range: 0 2

Avoidance maximum acceleration (AVOID_ACCEL_MAX)

Maximum acceleration with which obstacles will be avoided with. Set zero to disable acceleration limits

• Units: meters per square second
• Range: 0 9

Avoidance deadzone between stopping and backing away from obstacle (AVOID_BACKUP_DZ)

Distance beyond AVOID_MARGIN parameter, after which vehicle will backaway from obstacles. Increase this parameter if you see vehicle going back and forth in front of obstacle.

• Units: meters
• Range: 0 2

BARO Parameters

Ground Pressure (BARO1_GND_PRESS)

calibrated ground pressure in Pascals

• Units: pascal
• Increment: 1
• ReadOnly: True
• Volatile: True

ground temperature (BARO_GND_TEMP)

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.

• Units: degrees Celsius
• Increment: 1
• Volatile: True

altitude offset (BARO_ALT_OFFSET)

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.

• Units: meters
• Increment: 0.1

Primary barometer (BARO_PRIMARY)

This selects which barometer will be the primary if multiple barometers are found

Value	Meaning
0	FirstBaro
1	2ndBaro
2	3rdBaro

External baro bus (BARO_EXT_BUS)

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

Ground Pressure (BARO2_GND_PRESS)

calibrated ground pressure in Pascals

• Units: pascal
• Increment: 1
• ReadOnly: True
• Volatile: True

Absolute Pressure (BARO3_GND_PRESS)

calibrated ground pressure in Pascals

• Units: pascal
• Increment: 1
• ReadOnly: True
• Volatile: True

Range in which sample is accepted (BARO_FLTR_RNG)

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.

• Units: percent
• Range: 0 100
• Increment: 1

External barometers to probe (BARO_PROBE_EXT)

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.

• Bitmask: 0:BMP085,1:BMP280,2:MS5611,3:MS5607,4:MS5637,5:FBM320,6:DPS280,7:LPS25H,8:Keller,9:MS5837,10:BMP388,11:SPL06,12:MSP

Baro ID (BARO1_DEVID)

Barometer sensor ID, taking into account its type, bus and instance

• ReadOnly: True

Baro ID2 (BARO2_DEVID)

Barometer2 sensor ID, taking into account its type, bus and instance

• ReadOnly: True

Baro ID3 (BARO3_DEVID)

Barometer3 sensor ID, taking into account its type, bus and instance

• ReadOnly: True

field elevation (BARO_FIELD_ELV)

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.

• Units: meters
• Increment: 0.1
• Volatile: True

Altitude error maximum (BARO_ALTERR_MAX)

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.

• Units: meters
• Increment: 1
• Range: 0 5000

Barometer options (BARO_OPTIONS)

Barometer options

• Bitmask: 0:Treat MS5611 as MS5607

BARO1_WCF_ Parameters

Wind coefficient enable (BARO1_WCF_ENABLE)

This enables the use of wind coefficients for barometer compensation

Value	Meaning
0	Disabled
1	Enabled

Pressure error coefficient in positive X direction (forward) (BARO1_WCF_FWD)

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.

• Range: -1.0 1.0
• Increment: 0.05

Pressure error coefficient in negative X direction (backwards) (BARO1_WCF_BCK)

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.

• Range: -1.0 1.0
• Increment: 0.05

Pressure error coefficient in positive Y direction (right) (BARO1_WCF_RGT)

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.

• Range: -1.0 1.0
• Increment: 0.05

Pressure error coefficient in negative Y direction (left) (BARO1_WCF_LFT)

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.

• Range: -1.0 1.0
• Increment: 0.05

Pressure error coefficient in positive Z direction (up) (BARO1_WCF_UP)

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.

• Range: -1.0 1.0
• Increment: 0.05

Pressure error coefficient in negative Z direction (down) (BARO1_WCF_DN)

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.

• Range: -1.0 1.0
• Increment: 0.05

BARO2_WCF_ Parameters

Wind coefficient enable (BARO2_WCF_ENABLE)

This enables the use of wind coefficients for barometer compensation

Value	Meaning
0	Disabled
1	Enabled

Pressure error coefficient in positive X direction (forward) (BARO2_WCF_FWD)

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.

• Range: -1.0 1.0
• Increment: 0.05

Pressure error coefficient in negative X direction (backwards) (BARO2_WCF_BCK)

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.

• Range: -1.0 1.0
• Increment: 0.05

Pressure error coefficient in positive Y direction (right) (BARO2_WCF_RGT)

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.

• Range: -1.0 1.0
• Increment: 0.05

Pressure error coefficient in negative Y direction (left) (BARO2_WCF_LFT)

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.

• Range: -1.0 1.0
• Increment: 0.05

Pressure error coefficient in positive Z direction (up) (BARO2_WCF_UP)

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.

• Range: -1.0 1.0
• Increment: 0.05

Pressure error coefficient in negative Z direction (down) (BARO2_WCF_DN)

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.

• Range: -1.0 1.0
• Increment: 0.05

BARO3_WCF_ Parameters

Wind coefficient enable (BARO3_WCF_ENABLE)

This enables the use of wind coefficients for barometer compensation

Value	Meaning
0	Disabled
1	Enabled

Pressure error coefficient in positive X direction (forward) (BARO3_WCF_FWD)

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.

• Range: -1.0 1.0
• Increment: 0.05

Pressure error coefficient in negative X direction (backwards) (BARO3_WCF_BCK)

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.

• Range: -1.0 1.0
• Increment: 0.05

Pressure error coefficient in positive Y direction (right) (BARO3_WCF_RGT)

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.

• Range: -1.0 1.0
• Increment: 0.05

Pressure error coefficient in negative Y direction (left) (BARO3_WCF_LFT)

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.

• Range: -1.0 1.0
• Increment: 0.05

Pressure error coefficient in positive Z direction (up) (BARO3_WCF_UP)

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.

• Range: -1.0 1.0
• Increment: 0.05

Pressure error coefficient in negative Z direction (down) (BARO3_WCF_DN)

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.

• Range: -1.0 1.0
• Increment: 0.05

BATT2_ Parameters

Battery monitoring (BATT2_MONITOR)

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

• RebootRequired: True

Battery capacity (BATT2_CAPACITY)

Capacity of the battery in mAh when full

• Units: milliampere hour
• Increment: 50

Battery serial number (BATT2_SERIAL_NUM)

Battery serial number, automatically filled in for SMBus batteries, otherwise will be -1. With DroneCan it is the battery_id.

Low voltage timeout (BATT2_LOW_TIMER)

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.

• Units: seconds
• Increment: 1
• Range: 0 120

Failsafe voltage source (BATT2_FS_VOLTSRC)

Voltage type used for detection of low voltage event

Value	Meaning
0	Raw Voltage
1	Sag Compensated Voltage

Low battery voltage (BATT2_LOW_VOLT)

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.

• Units: volt
• Increment: 0.1

Low battery capacity (BATT2_LOW_MAH)

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.

• Units: milliampere hour
• Increment: 50

Critical battery voltage (BATT2_CRT_VOLT)

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.

• Units: volt
• Increment: 0.1

Battery critical capacity (BATT2_CRT_MAH)

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.

• Units: milliampere hour
• Increment: 50

Low battery failsafe action (BATT2_FS_LOW_ACT)

What action the vehicle should perform if it hits a low battery failsafe

Value	Meaning
0	None
1	RTL
2	Hold
3	SmartRTL
4	SmartRTL or Hold
5	Terminate

Critical battery failsafe action (BATT2_FS_CRT_ACT)

What action the vehicle should perform if it hits a critical battery failsafe

Value	Meaning
0	None
1	RTL
2	Hold
3	SmartRTL
4	SmartRTL or Hold
5	Terminate

Required arming voltage (BATT2_ARM_VOLT)

Battery voltage level which is required to arm the aircraft. Set to 0 to allow arming at any voltage.

• Units: volt
• Increment: 0.1

Required arming remaining capacity (BATT2_ARM_MAH)

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.

• Units: milliampere hour
• Increment: 50

Battery monitor options (BATT2_OPTIONS)

This sets options to change the behaviour of the battery monitor

• Bitmask: 0:Ignore DroneCAN SoC, 1:MPPT reports input voltage and current, 2:MPPT Powered off when disarmed, 3:MPPT Powered on when armed, 4:MPPT Powered off at boot, 5:MPPT Powered on at boot, 6:Send resistance compensated voltage to GCS

Battery Voltage sensing pin (BATT2_VOLT_PIN)

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

• RebootRequired: True

Battery Current sensing pin (BATT2_CURR_PIN)

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

• RebootRequired: True

Voltage Multiplier (BATT2_VOLT_MULT)

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.

Amps per volt (BATT2_AMP_PERVLT)

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.

• Units: ampere per volt

AMP offset (BATT2_AMP_OFFSET)

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.

• Units: volt

Voltage offset (BATT2_VLT_OFFSET)

Voltage offset on voltage pin. This allows for an offset due to a diode. This voltage is subtracted before the scaling is applied.

• Units: volt

Battery monitor I2C bus number (BATT2_I2C_BUS)

Battery monitor I2C bus number

• Range: 0 3
• RebootRequired: True

Battery monitor I2C address (BATT2_I2C_ADDR)

Battery monitor I2C address

• Range: 0 127
• RebootRequired: True

Battery Sum mask (BATT2_SUM_MASK)

0: sum of remaining battery monitors, If none 0 sum of specified monitors. Current will be summed and voltages averaged.

• Bitmask: 0:monitor 1, 1:monitor 2, 2:monitor 3, 3:monitor 4, 4:monitor 5, 5:monitor 6, 6:monitor 7, 7:monitor 8, 8:monitor 9

Scales reported power monitor current (BATT2_CURR_MULT)

Multiplier applied to all current related reports to allow for adjustment if no UAVCAN param access or current splitting applications

• Range: .1 10

Empty fuel level voltage (BATT2_FL_VLT_MIN)

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.

• Range: 0.01 10
• Units: volt

Fuel level voltage multiplier (BATT2_FL_V_MULT)

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.

• Range: 0.01 10

Fuel level filter frequency (BATT2_FL_FLTR)

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.

• Range: -1 1
• Units: hertz
• RebootRequired: True

Fuel level analog pin number (BATT2_FL_PIN)

Analog input pin that fuel level sensor is connected to. Airspeed ports can be used for Analog input. When using analog pin 103, the maximum value of the input in 3.3V.

Value	Meaning
-1	Not Used
11	Pixracer
13	Pixhawk ADC4
14	Pixhawk ADC3
15	Pixhawk ADC6/Pixhawk2 ADC
103	Pixhawk SBUS

Maximum Battery Voltage (BATT2_MAX_VOLT)

Maximum voltage of battery. Provides scaling of current versus voltage

• Range: 7 100

BATT3_ Parameters

Battery monitoring (BATT3_MONITOR)

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

• RebootRequired: True

Battery capacity (BATT3_CAPACITY)

Capacity of the battery in mAh when full

• Units: milliampere hour
• Increment: 50

Battery serial number (BATT3_SERIAL_NUM)

Battery serial number, automatically filled in for SMBus batteries, otherwise will be -1. With DroneCan it is the battery_id.

Low voltage timeout (BATT3_LOW_TIMER)

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.

• Units: seconds
• Increment: 1
• Range: 0 120

Failsafe voltage source (BATT3_FS_VOLTSRC)

Voltage type used for detection of low voltage event

Value	Meaning
0	Raw Voltage
1	Sag Compensated Voltage

Low battery voltage (BATT3_LOW_VOLT)

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.

• Units: volt
• Increment: 0.1

Low battery capacity (BATT3_LOW_MAH)

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.

• Units: milliampere hour
• Increment: 50

Critical battery voltage (BATT3_CRT_VOLT)

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.

• Units: volt
• Increment: 0.1

Battery critical capacity (BATT3_CRT_MAH)

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.

• Units: milliampere hour
• Increment: 50

Low battery failsafe action (BATT3_FS_LOW_ACT)

What action the vehicle should perform if it hits a low battery failsafe

Value	Meaning
0	None
1	RTL
2	Hold
3	SmartRTL
4	SmartRTL or Hold
5	Terminate

Critical battery failsafe action (BATT3_FS_CRT_ACT)

What action the vehicle should perform if it hits a critical battery failsafe

Value	Meaning
0	None
1	RTL
2	Hold
3	SmartRTL
4	SmartRTL or Hold
5	Terminate

Required arming voltage (BATT3_ARM_VOLT)

Battery voltage level which is required to arm the aircraft. Set to 0 to allow arming at any voltage.

• Units: volt
• Increment: 0.1

Required arming remaining capacity (BATT3_ARM_MAH)

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.

• Units: milliampere hour
• Increment: 50

Battery monitor options (BATT3_OPTIONS)

This sets options to change the behaviour of the battery monitor

• Bitmask: 0:Ignore DroneCAN SoC, 1:MPPT reports input voltage and current, 2:MPPT Powered off when disarmed, 3:MPPT Powered on when armed, 4:MPPT Powered off at boot, 5:MPPT Powered on at boot, 6:Send resistance compensated voltage to GCS

Battery Voltage sensing pin (BATT3_VOLT_PIN)

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

• RebootRequired: True

Battery Current sensing pin (BATT3_CURR_PIN)

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

• RebootRequired: True

Voltage Multiplier (BATT3_VOLT_MULT)

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.

Amps per volt (BATT3_AMP_PERVLT)

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.

• Units: ampere per volt

AMP offset (BATT3_AMP_OFFSET)

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.

• Units: volt

Voltage offset (BATT3_VLT_OFFSET)

Voltage offset on voltage pin. This allows for an offset due to a diode. This voltage is subtracted before the scaling is applied.

• Units: volt

Battery monitor I2C bus number (BATT3_I2C_BUS)

Battery monitor I2C bus number

• Range: 0 3
• RebootRequired: True

Battery monitor I2C address (BATT3_I2C_ADDR)

Battery monitor I2C address

• Range: 0 127
• RebootRequired: True

Battery Sum mask (BATT3_SUM_MASK)

0: sum of remaining battery monitors, If none 0 sum of specified monitors. Current will be summed and voltages averaged.

• Bitmask: 0:monitor 1, 1:monitor 2, 2:monitor 3, 3:monitor 4, 4:monitor 5, 5:monitor 6, 6:monitor 7, 7:monitor 8, 8:monitor 9

Scales reported power monitor current (BATT3_CURR_MULT)

Multiplier applied to all current related reports to allow for adjustment if no UAVCAN param access or current splitting applications

• Range: .1 10

Empty fuel level voltage (BATT3_FL_VLT_MIN)

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.

• Range: 0.01 10
• Units: volt

Fuel level voltage multiplier (BATT3_FL_V_MULT)

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.

• Range: 0.01 10

Fuel level filter frequency (BATT3_FL_FLTR)

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.

• Range: -1 1
• Units: hertz
• RebootRequired: True

Fuel level analog pin number (BATT3_FL_PIN)

Analog input pin that fuel level sensor is connected to. Airspeed ports can be used for Analog input. When using analog pin 103, the maximum value of the input in 3.3V.

Value	Meaning
-1	Not Used
11	Pixracer
13	Pixhawk ADC4
14	Pixhawk ADC3
15	Pixhawk ADC6/Pixhawk2 ADC
103	Pixhawk SBUS

Maximum Battery Voltage (BATT3_MAX_VOLT)

Maximum voltage of battery. Provides scaling of current versus voltage

• Range: 7 100

BATT4_ Parameters

Battery monitoring (BATT4_MONITOR)

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

• RebootRequired: True

Battery capacity (BATT4_CAPACITY)

Capacity of the battery in mAh when full

• Units: milliampere hour
• Increment: 50

Battery serial number (BATT4_SERIAL_NUM)

Battery serial number, automatically filled in for SMBus batteries, otherwise will be -1. With DroneCan it is the battery_id.

Low voltage timeout (BATT4_LOW_TIMER)

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.

• Units: seconds
• Increment: 1
• Range: 0 120

Failsafe voltage source (BATT4_FS_VOLTSRC)

Voltage type used for detection of low voltage event

Value	Meaning
0	Raw Voltage
1	Sag Compensated Voltage

Low battery voltage (BATT4_LOW_VOLT)

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.

• Units: volt
• Increment: 0.1

Low battery capacity (BATT4_LOW_MAH)

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.

• Units: milliampere hour
• Increment: 50

Critical battery voltage (BATT4_CRT_VOLT)

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.

• Units: volt
• Increment: 0.1

Battery critical capacity (BATT4_CRT_MAH)

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.

• Units: milliampere hour
• Increment: 50

Low battery failsafe action (BATT4_FS_LOW_ACT)

What action the vehicle should perform if it hits a low battery failsafe

Value	Meaning
0	None
1	RTL
2	Hold
3	SmartRTL
4	SmartRTL or Hold
5	Terminate

Critical battery failsafe action (BATT4_FS_CRT_ACT)

What action the vehicle should perform if it hits a critical battery failsafe

Value	Meaning
0	None
1	RTL
2	Hold
3	SmartRTL
4	SmartRTL or Hold
5	Terminate

Required arming voltage (BATT4_ARM_VOLT)

Battery voltage level which is required to arm the aircraft. Set to 0 to allow arming at any voltage.

• Units: volt
• Increment: 0.1

Required arming remaining capacity (BATT4_ARM_MAH)

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.

• Units: milliampere hour
• Increment: 50

Battery monitor options (BATT4_OPTIONS)

This sets options to change the behaviour of the battery monitor

• Bitmask: 0:Ignore DroneCAN SoC, 1:MPPT reports input voltage and current, 2:MPPT Powered off when disarmed, 3:MPPT Powered on when armed, 4:MPPT Powered off at boot, 5:MPPT Powered on at boot, 6:Send resistance compensated voltage to GCS

Battery Voltage sensing pin (BATT4_VOLT_PIN)

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

• RebootRequired: True

Battery Current sensing pin (BATT4_CURR_PIN)

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

• RebootRequired: True

Voltage Multiplier (BATT4_VOLT_MULT)

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.

Amps per volt (BATT4_AMP_PERVLT)

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.

• Units: ampere per volt

AMP offset (BATT4_AMP_OFFSET)

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.

• Units: volt

Voltage offset (BATT4_VLT_OFFSET)

Voltage offset on voltage pin. This allows for an offset due to a diode. This voltage is subtracted before the scaling is applied.

• Units: volt

Battery monitor I2C bus number (BATT4_I2C_BUS)

Battery monitor I2C bus number

• Range: 0 3
• RebootRequired: True

Battery monitor I2C address (BATT4_I2C_ADDR)

Battery monitor I2C address

• Range: 0 127
• RebootRequired: True

Battery Sum mask (BATT4_SUM_MASK)

0: sum of remaining battery monitors, If none 0 sum of specified monitors. Current will be summed and voltages averaged.

• Bitmask: 0:monitor 1, 1:monitor 2, 2:monitor 3, 3:monitor 4, 4:monitor 5, 5:monitor 6, 6:monitor 7, 7:monitor 8, 8:monitor 9

Scales reported power monitor current (BATT4_CURR_MULT)

Multiplier applied to all current related reports to allow for adjustment if no UAVCAN param access or current splitting applications

• Range: .1 10

Empty fuel level voltage (BATT4_FL_VLT_MIN)

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.

• Range: 0.01 10
• Units: volt

Fuel level voltage multiplier (BATT4_FL_V_MULT)

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.

• Range: 0.01 10

Fuel level filter frequency (BATT4_FL_FLTR)

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.

• Range: -1 1
• Units: hertz
• RebootRequired: True

Fuel level analog pin number (BATT4_FL_PIN)

Analog input pin that fuel level sensor is connected to. Airspeed ports can be used for Analog input. When using analog pin 103, the maximum value of the input in 3.3V.

Value	Meaning
-1	Not Used
11	Pixracer
13	Pixhawk ADC4
14	Pixhawk ADC3
15	Pixhawk ADC6/Pixhawk2 ADC
103	Pixhawk SBUS

Maximum Battery Voltage (BATT4_MAX_VOLT)

Maximum voltage of battery. Provides scaling of current versus voltage

• Range: 7 100

BATT5_ Parameters

Battery monitoring (BATT5_MONITOR)

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

• RebootRequired: True

Battery capacity (BATT5_CAPACITY)

Capacity of the battery in mAh when full

• Units: milliampere hour
• Increment: 50

Battery serial number (BATT5_SERIAL_NUM)

Battery serial number, automatically filled in for SMBus batteries, otherwise will be -1. With DroneCan it is the battery_id.

Low voltage timeout (BATT5_LOW_TIMER)

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.

• Units: seconds
• Increment: 1
• Range: 0 120

Failsafe voltage source (BATT5_FS_VOLTSRC)

Voltage type used for detection of low voltage event

Value	Meaning
0	Raw Voltage
1	Sag Compensated Voltage

Low battery voltage (BATT5_LOW_VOLT)

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.

• Units: volt
• Increment: 0.1

Low battery capacity (BATT5_LOW_MAH)

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.

• Units: milliampere hour
• Increment: 50

Critical battery voltage (BATT5_CRT_VOLT)

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.

• Units: volt
• Increment: 0.1

Battery critical capacity (BATT5_CRT_MAH)

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.

• Units: milliampere hour
• Increment: 50

Low battery failsafe action (BATT5_FS_LOW_ACT)

What action the vehicle should perform if it hits a low battery failsafe

Value	Meaning
0	None
1	RTL
2	Hold
3	SmartRTL
4	SmartRTL or Hold
5	Terminate

Critical battery failsafe action (BATT5_FS_CRT_ACT)

What action the vehicle should perform if it hits a critical battery failsafe

Value	Meaning
0	None
1	RTL
2	Hold
3	SmartRTL
4	SmartRTL or Hold
5	Terminate

Required arming voltage (BATT5_ARM_VOLT)

Battery voltage level which is required to arm the aircraft. Set to 0 to allow arming at any voltage.

• Units: volt
• Increment: 0.1

Required arming remaining capacity (BATT5_ARM_MAH)

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.

• Units: milliampere hour
• Increment: 50

Battery monitor options (BATT5_OPTIONS)

This sets options to change the behaviour of the battery monitor

• Bitmask: 0:Ignore DroneCAN SoC, 1:MPPT reports input voltage and current, 2:MPPT Powered off when disarmed, 3:MPPT Powered on when armed, 4:MPPT Powered off at boot, 5:MPPT Powered on at boot, 6:Send resistance compensated voltage to GCS

Battery Voltage sensing pin (BATT5_VOLT_PIN)

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

• RebootRequired: True

Battery Current sensing pin (BATT5_CURR_PIN)

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

• RebootRequired: True

Voltage Multiplier (BATT5_VOLT_MULT)

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.

Amps per volt (BATT5_AMP_PERVLT)

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.

• Units: ampere per volt

AMP offset (BATT5_AMP_OFFSET)

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.

• Units: volt

Voltage offset (BATT5_VLT_OFFSET)

Voltage offset on voltage pin. This allows for an offset due to a diode. This voltage is subtracted before the scaling is applied.

• Units: volt

Battery monitor I2C bus number (BATT5_I2C_BUS)

Battery monitor I2C bus number

• Range: 0 3
• RebootRequired: True

Battery monitor I2C address (BATT5_I2C_ADDR)

Battery monitor I2C address

• Range: 0 127
• RebootRequired: True

Battery Sum mask (BATT5_SUM_MASK)

0: sum of remaining battery monitors, If none 0 sum of specified monitors. Current will be summed and voltages averaged.

• Bitmask: 0:monitor 1, 1:monitor 2, 2:monitor 3, 3:monitor 4, 4:monitor 5, 5:monitor 6, 6:monitor 7, 7:monitor 8, 8:monitor 9

Scales reported power monitor current (BATT5_CURR_MULT)

Multiplier applied to all current related reports to allow for adjustment if no UAVCAN param access or current splitting applications

• Range: .1 10

Empty fuel level voltage (BATT5_FL_VLT_MIN)

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.

• Range: 0.01 10
• Units: volt

Fuel level voltage multiplier (BATT5_FL_V_MULT)

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.

• Range: 0.01 10

Fuel level filter frequency (BATT5_FL_FLTR)

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.

• Range: -1 1
• Units: hertz
• RebootRequired: True

Fuel level analog pin number (BATT5_FL_PIN)

Analog input pin that fuel level sensor is connected to. Airspeed ports can be used for Analog input. When using analog pin 103, the maximum value of the input in 3.3V.

Value	Meaning
-1	Not Used
11	Pixracer
13	Pixhawk ADC4
14	Pixhawk ADC3
15	Pixhawk ADC6/Pixhawk2 ADC
103	Pixhawk SBUS

Maximum Battery Voltage (BATT5_MAX_VOLT)

Maximum voltage of battery. Provides scaling of current versus voltage

• Range: 7 100

BATT6_ Parameters

Battery monitoring (BATT6_MONITOR)

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

• RebootRequired: True

Battery capacity (BATT6_CAPACITY)

Capacity of the battery in mAh when full

• Units: milliampere hour
• Increment: 50

Battery serial number (BATT6_SERIAL_NUM)

Battery serial number, automatically filled in for SMBus batteries, otherwise will be -1. With DroneCan it is the battery_id.

Low voltage timeout (BATT6_LOW_TIMER)

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.

• Units: seconds
• Increment: 1
• Range: 0 120

Failsafe voltage source (BATT6_FS_VOLTSRC)

Voltage type used for detection of low voltage event

Value	Meaning
0	Raw Voltage
1	Sag Compensated Voltage

Low battery voltage (BATT6_LOW_VOLT)

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.

• Units: volt
• Increment: 0.1

Low battery capacity (BATT6_LOW_MAH)

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.

• Units: milliampere hour
• Increment: 50

Critical battery voltage (BATT6_CRT_VOLT)

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.

• Units: volt
• Increment: 0.1

Battery critical capacity (BATT6_CRT_MAH)

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.

• Units: milliampere hour
• Increment: 50

Low battery failsafe action (BATT6_FS_LOW_ACT)

What action the vehicle should perform if it hits a low battery failsafe

Value	Meaning
0	None
1	RTL
2	Hold
3	SmartRTL
4	SmartRTL or Hold
5	Terminate

Critical battery failsafe action (BATT6_FS_CRT_ACT)

What action the vehicle should perform if it hits a critical battery failsafe

Value	Meaning
0	None
1	RTL
2	Hold
3	SmartRTL
4	SmartRTL or Hold
5	Terminate

Required arming voltage (BATT6_ARM_VOLT)

Battery voltage level which is required to arm the aircraft. Set to 0 to allow arming at any voltage.

• Units: volt
• Increment: 0.1

Required arming remaining capacity (BATT6_ARM_MAH)

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.

• Units: milliampere hour
• Increment: 50

Battery monitor options (BATT6_OPTIONS)

This sets options to change the behaviour of the battery monitor

• Bitmask: 0:Ignore DroneCAN SoC, 1:MPPT reports input voltage and current, 2:MPPT Powered off when disarmed, 3:MPPT Powered on when armed, 4:MPPT Powered off at boot, 5:MPPT Powered on at boot, 6:Send resistance compensated voltage to GCS

Battery Voltage sensing pin (BATT6_VOLT_PIN)

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

• RebootRequired: True

Battery Current sensing pin (BATT6_CURR_PIN)

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

• RebootRequired: True

Voltage Multiplier (BATT6_VOLT_MULT)

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.

Amps per volt (BATT6_AMP_PERVLT)

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.

• Units: ampere per volt

AMP offset (BATT6_AMP_OFFSET)

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.

• Units: volt

Voltage offset (BATT6_VLT_OFFSET)

Voltage offset on voltage pin. This allows for an offset due to a diode. This voltage is subtracted before the scaling is applied.

• Units: volt

Battery monitor I2C bus number (BATT6_I2C_BUS)

Battery monitor I2C bus number

• Range: 0 3
• RebootRequired: True

Battery monitor I2C address (BATT6_I2C_ADDR)

Battery monitor I2C address

• Range: 0 127
• RebootRequired: True

Battery Sum mask (BATT6_SUM_MASK)

0: sum of remaining battery monitors, If none 0 sum of specified monitors. Current will be summed and voltages averaged.

• Bitmask: 0:monitor 1, 1:monitor 2, 2:monitor 3, 3:monitor 4, 4:monitor 5, 5:monitor 6, 6:monitor 7, 7:monitor 8, 8:monitor 9

Scales reported power monitor current (BATT6_CURR_MULT)

Multiplier applied to all current related reports to allow for adjustment if no UAVCAN param access or current splitting applications

• Range: .1 10

Empty fuel level voltage (BATT6_FL_VLT_MIN)

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.

• Range: 0.01 10
• Units: volt

Fuel level voltage multiplier (BATT6_FL_V_MULT)

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.

• Range: 0.01 10

Fuel level filter frequency (BATT6_FL_FLTR)

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.

• Range: -1 1
• Units: hertz
• RebootRequired: True

Fuel level analog pin number (BATT6_FL_PIN)

Analog input pin that fuel level sensor is connected to. Airspeed ports can be used for Analog input. When using analog pin 103, the maximum value of the input in 3.3V.

Value	Meaning
-1	Not Used
11	Pixracer
13	Pixhawk ADC4
14	Pixhawk ADC3
15	Pixhawk ADC6/Pixhawk2 ADC
103	Pixhawk SBUS

Maximum Battery Voltage (BATT6_MAX_VOLT)

Maximum voltage of battery. Provides scaling of current versus voltage

• Range: 7 100

BATT7_ Parameters

Battery monitoring (BATT7_MONITOR)

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

• RebootRequired: True

Battery capacity (BATT7_CAPACITY)

Capacity of the battery in mAh when full

• Units: milliampere hour
• Increment: 50

Battery serial number (BATT7_SERIAL_NUM)

Battery serial number, automatically filled in for SMBus batteries, otherwise will be -1. With DroneCan it is the battery_id.

Low voltage timeout (BATT7_LOW_TIMER)

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.

• Units: seconds
• Increment: 1
• Range: 0 120

Failsafe voltage source (BATT7_FS_VOLTSRC)

Voltage type used for detection of low voltage event

Value	Meaning
0	Raw Voltage
1	Sag Compensated Voltage

Low battery voltage (BATT7_LOW_VOLT)

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.

• Units: volt
• Increment: 0.1

Low battery capacity (BATT7_LOW_MAH)

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.

• Units: milliampere hour
• Increment: 50

Critical battery voltage (BATT7_CRT_VOLT)

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.

• Units: volt
• Increment: 0.1

Battery critical capacity (BATT7_CRT_MAH)

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.

• Units: milliampere hour
• Increment: 50

Low battery failsafe action (BATT7_FS_LOW_ACT)

What action the vehicle should perform if it hits a low battery failsafe

Value	Meaning
0	None
1	RTL
2	Hold
3	SmartRTL
4	SmartRTL or Hold
5	Terminate

Critical battery failsafe action (BATT7_FS_CRT_ACT)

What action the vehicle should perform if it hits a critical battery failsafe

Value	Meaning
0	None
1	RTL
2	Hold
3	SmartRTL
4	SmartRTL or Hold
5	Terminate

Required arming voltage (BATT7_ARM_VOLT)

Battery voltage level which is required to arm the aircraft. Set to 0 to allow arming at any voltage.

• Units: volt
• Increment: 0.1

Required arming remaining capacity (BATT7_ARM_MAH)

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.

• Units: milliampere hour
• Increment: 50

Battery monitor options (BATT7_OPTIONS)

This sets options to change the behaviour of the battery monitor

• Bitmask: 0:Ignore DroneCAN SoC, 1:MPPT reports input voltage and current, 2:MPPT Powered off when disarmed, 3:MPPT Powered on when armed, 4:MPPT Powered off at boot, 5:MPPT Powered on at boot, 6:Send resistance compensated voltage to GCS

Battery Voltage sensing pin (BATT7_VOLT_PIN)

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

• RebootRequired: True

Battery Current sensing pin (BATT7_CURR_PIN)

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

• RebootRequired: True

Voltage Multiplier (BATT7_VOLT_MULT)

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.

Amps per volt (BATT7_AMP_PERVLT)

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.

• Units: ampere per volt

AMP offset (BATT7_AMP_OFFSET)

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.

• Units: volt

Voltage offset (BATT7_VLT_OFFSET)

Voltage offset on voltage pin. This allows for an offset due to a diode. This voltage is subtracted before the scaling is applied.

• Units: volt

Battery monitor I2C bus number (BATT7_I2C_BUS)

Battery monitor I2C bus number

• Range: 0 3
• RebootRequired: True

Battery monitor I2C address (BATT7_I2C_ADDR)

Battery monitor I2C address

• Range: 0 127
• RebootRequired: True

Battery Sum mask (BATT7_SUM_MASK)

0: sum of remaining battery monitors, If none 0 sum of specified monitors. Current will be summed and voltages averaged.

• Bitmask: 0:monitor 1, 1:monitor 2, 2:monitor 3, 3:monitor 4, 4:monitor 5, 5:monitor 6, 6:monitor 7, 7:monitor 8, 8:monitor 9

Scales reported power monitor current (BATT7_CURR_MULT)

Multiplier applied to all current related reports to allow for adjustment if no UAVCAN param access or current splitting applications

• Range: .1 10

Empty fuel level voltage (BATT7_FL_VLT_MIN)

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.

• Range: 0.01 10
• Units: volt

Fuel level voltage multiplier (BATT7_FL_V_MULT)

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.

• Range: 0.01 10

Fuel level filter frequency (BATT7_FL_FLTR)

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.

• Range: -1 1
• Units: hertz
• RebootRequired: True

Fuel level analog pin number (BATT7_FL_PIN)

Analog input pin that fuel level sensor is connected to. Airspeed ports can be used for Analog input. When using analog pin 103, the maximum value of the input in 3.3V.

Value	Meaning
-1	Not Used
11	Pixracer
13	Pixhawk ADC4
14	Pixhawk ADC3
15	Pixhawk ADC6/Pixhawk2 ADC
103	Pixhawk SBUS

Maximum Battery Voltage (BATT7_MAX_VOLT)

Maximum voltage of battery. Provides scaling of current versus voltage

• Range: 7 100

BATT8_ Parameters

Battery monitoring (BATT8_MONITOR)

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

• RebootRequired: True

Battery capacity (BATT8_CAPACITY)

Capacity of the battery in mAh when full

• Units: milliampere hour
• Increment: 50

Battery serial number (BATT8_SERIAL_NUM)

Battery serial number, automatically filled in for SMBus batteries, otherwise will be -1. With DroneCan it is the battery_id.

Low voltage timeout (BATT8_LOW_TIMER)

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.

• Units: seconds
• Increment: 1
• Range: 0 120

Failsafe voltage source (BATT8_FS_VOLTSRC)

Voltage type used for detection of low voltage event

Value	Meaning
0	Raw Voltage
1	Sag Compensated Voltage

Low battery voltage (BATT8_LOW_VOLT)

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.

• Units: volt
• Increment: 0.1

Low battery capacity (BATT8_LOW_MAH)

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.

• Units: milliampere hour
• Increment: 50

Critical battery voltage (BATT8_CRT_VOLT)

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.

• Units: volt
• Increment: 0.1

Battery critical capacity (BATT8_CRT_MAH)

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.

• Units: milliampere hour
• Increment: 50

Low battery failsafe action (BATT8_FS_LOW_ACT)

What action the vehicle should perform if it hits a low battery failsafe

Value	Meaning
0	None
1	RTL
2	Hold
3	SmartRTL
4	SmartRTL or Hold
5	Terminate

Critical battery failsafe action (BATT8_FS_CRT_ACT)

What action the vehicle should perform if it hits a critical battery failsafe

Value	Meaning
0	None
1	RTL
2	Hold
3	SmartRTL
4	SmartRTL or Hold
5	Terminate

Required arming voltage (BATT8_ARM_VOLT)

Battery voltage level which is required to arm the aircraft. Set to 0 to allow arming at any voltage.

• Units: volt
• Increment: 0.1

Required arming remaining capacity (BATT8_ARM_MAH)

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.

• Units: milliampere hour
• Increment: 50

Battery monitor options (BATT8_OPTIONS)

This sets options to change the behaviour of the battery monitor

• Bitmask: 0:Ignore DroneCAN SoC, 1:MPPT reports input voltage and current, 2:MPPT Powered off when disarmed, 3:MPPT Powered on when armed, 4:MPPT Powered off at boot, 5:MPPT Powered on at boot, 6:Send resistance compensated voltage to GCS

Battery Voltage sensing pin (BATT8_VOLT_PIN)

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

• RebootRequired: True

Battery Current sensing pin (BATT8_CURR_PIN)

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

• RebootRequired: True

Voltage Multiplier (BATT8_VOLT_MULT)

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.

Amps per volt (BATT8_AMP_PERVLT)

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.

• Units: ampere per volt

AMP offset (BATT8_AMP_OFFSET)

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.

• Units: volt

Voltage offset (BATT8_VLT_OFFSET)

Voltage offset on voltage pin. This allows for an offset due to a diode. This voltage is subtracted before the scaling is applied.

• Units: volt

Battery monitor I2C bus number (BATT8_I2C_BUS)

Battery monitor I2C bus number

• Range: 0 3
• RebootRequired: True

Battery monitor I2C address (BATT8_I2C_ADDR)

Battery monitor I2C address

• Range: 0 127
• RebootRequired: True

Battery Sum mask (BATT8_SUM_MASK)

0: sum of remaining battery monitors, If none 0 sum of specified monitors. Current will be summed and voltages averaged.

• Bitmask: 0:monitor 1, 1:monitor 2, 2:monitor 3, 3:monitor 4, 4:monitor 5, 5:monitor 6, 6:monitor 7, 7:monitor 8, 8:monitor 9

Scales reported power monitor current (BATT8_CURR_MULT)

Multiplier applied to all current related reports to allow for adjustment if no UAVCAN param access or current splitting applications

• Range: .1 10

Empty fuel level voltage (BATT8_FL_VLT_MIN)

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.

• Range: 0.01 10
• Units: volt

Fuel level voltage multiplier (BATT8_FL_V_MULT)

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.

• Range: 0.01 10

Fuel level filter frequency (BATT8_FL_FLTR)

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.

• Range: -1 1
• Units: hertz
• RebootRequired: True

Fuel level analog pin number (BATT8_FL_PIN)

Analog input pin that fuel level sensor is connected to. Airspeed ports can be used for Analog input. When using analog pin 103, the maximum value of the input in 3.3V.

Value	Meaning
-1	Not Used
11	Pixracer
13	Pixhawk ADC4
14	Pixhawk ADC3
15	Pixhawk ADC6/Pixhawk2 ADC
103	Pixhawk SBUS

Maximum Battery Voltage (BATT8_MAX_VOLT)

Maximum voltage of battery. Provides scaling of current versus voltage

• Range: 7 100

BATT9_ Parameters

Battery monitoring (BATT9_MONITOR)

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

• RebootRequired: True

Battery capacity (BATT9_CAPACITY)

Capacity of the battery in mAh when full

• Units: milliampere hour
• Increment: 50

Battery serial number (BATT9_SERIAL_NUM)

Battery serial number, automatically filled in for SMBus batteries, otherwise will be -1. With DroneCan it is the battery_id.

Low voltage timeout (BATT9_LOW_TIMER)

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.

• Units: seconds
• Increment: 1
• Range: 0 120

Failsafe voltage source (BATT9_FS_VOLTSRC)

Voltage type used for detection of low voltage event

Value	Meaning
0	Raw Voltage
1	Sag Compensated Voltage

Low battery voltage (BATT9_LOW_VOLT)

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.

• Units: volt
• Increment: 0.1

Low battery capacity (BATT9_LOW_MAH)

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.

• Units: milliampere hour
• Increment: 50

Critical battery voltage (BATT9_CRT_VOLT)

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.

• Units: volt
• Increment: 0.1

Battery critical capacity (BATT9_CRT_MAH)

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.

• Units: milliampere hour
• Increment: 50

Low battery failsafe action (BATT9_FS_LOW_ACT)

What action the vehicle should perform if it hits a low battery failsafe

Value	Meaning
0	None
1	RTL
2	Hold
3	SmartRTL
4	SmartRTL or Hold
5	Terminate

Critical battery failsafe action (BATT9_FS_CRT_ACT)

What action the vehicle should perform if it hits a critical battery failsafe

Value	Meaning
0	None
1	RTL
2	Hold
3	SmartRTL
4	SmartRTL or Hold
5	Terminate

Required arming voltage (BATT9_ARM_VOLT)

Battery voltage level which is required to arm the aircraft. Set to 0 to allow arming at any voltage.

• Units: volt
• Increment: 0.1

Required arming remaining capacity (BATT9_ARM_MAH)

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.

• Units: milliampere hour
• Increment: 50

Battery monitor options (BATT9_OPTIONS)

This sets options to change the behaviour of the battery monitor

• Bitmask: 0:Ignore DroneCAN SoC, 1:MPPT reports input voltage and current, 2:MPPT Powered off when disarmed, 3:MPPT Powered on when armed, 4:MPPT Powered off at boot, 5:MPPT Powered on at boot, 6:Send resistance compensated voltage to GCS

Battery Voltage sensing pin (BATT9_VOLT_PIN)

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

• RebootRequired: True

Battery Current sensing pin (BATT9_CURR_PIN)

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

• RebootRequired: True

Voltage Multiplier (BATT9_VOLT_MULT)

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.

Amps per volt (BATT9_AMP_PERVLT)

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.

• Units: ampere per volt

AMP offset (BATT9_AMP_OFFSET)

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.

• Units: volt

Voltage offset (BATT9_VLT_OFFSET)

Voltage offset on voltage pin. This allows for an offset due to a diode. This voltage is subtracted before the scaling is applied.

• Units: volt

Battery monitor I2C bus number (BATT9_I2C_BUS)

Battery monitor I2C bus number

• Range: 0 3
• RebootRequired: True

Battery monitor I2C address (BATT9_I2C_ADDR)

Battery monitor I2C address

• Range: 0 127
• RebootRequired: True

Battery Sum mask (BATT9_SUM_MASK)

0: sum of remaining battery monitors, If none 0 sum of specified monitors. Current will be summed and voltages averaged.

• Bitmask: 0:monitor 1, 1:monitor 2, 2:monitor 3, 3:monitor 4, 4:monitor 5, 5:monitor 6, 6:monitor 7, 7:monitor 8, 8:monitor 9

Scales reported power monitor current (BATT9_CURR_MULT)

Multiplier applied to all current related reports to allow for adjustment if no UAVCAN param access or current splitting applications

• Range: .1 10

Empty fuel level voltage (BATT9_FL_VLT_MIN)

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.

• Range: 0.01 10
• Units: volt

Fuel level voltage multiplier (BATT9_FL_V_MULT)

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.

• Range: 0.01 10

Fuel level filter frequency (BATT9_FL_FLTR)

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.

• Range: -1 1
• Units: hertz
• RebootRequired: True

Fuel level analog pin number (BATT9_FL_PIN)

Analog input pin that fuel level sensor is connected to. Airspeed ports can be used for Analog input. When using analog pin 103, the maximum value of the input in 3.3V.

Value	Meaning
-1	Not Used
11	Pixracer
13	Pixhawk ADC4
14	Pixhawk ADC3
15	Pixhawk ADC6/Pixhawk2 ADC
103	Pixhawk SBUS

Maximum Battery Voltage (BATT9_MAX_VOLT)

Maximum voltage of battery. Provides scaling of current versus voltage

• Range: 7 100

BATT_ Parameters

Battery monitoring (BATT_MONITOR)

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

• RebootRequired: True

Battery capacity (BATT_CAPACITY)

Capacity of the battery in mAh when full

• Units: milliampere hour
• Increment: 50

Battery serial number (BATT_SERIAL_NUM)

Battery serial number, automatically filled in for SMBus batteries, otherwise will be -1. With DroneCan it is the battery_id.

Low voltage timeout (BATT_LOW_TIMER)

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.

• Units: seconds
• Increment: 1
• Range: 0 120

Failsafe voltage source (BATT_FS_VOLTSRC)

Voltage type used for detection of low voltage event

Value	Meaning
0	Raw Voltage
1	Sag Compensated Voltage

Low battery voltage (BATT_LOW_VOLT)

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.

• Units: volt
• Increment: 0.1

Low battery capacity (BATT_LOW_MAH)

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.

• Units: milliampere hour
• Increment: 50

Critical battery voltage (BATT_CRT_VOLT)

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.

• Units: volt
• Increment: 0.1

Battery critical capacity (BATT_CRT_MAH)

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.

• Units: milliampere hour
• Increment: 50

Low battery failsafe action (BATT_FS_LOW_ACT)

What action the vehicle should perform if it hits a low battery failsafe

Value	Meaning
0	None
1	RTL
2	Hold
3	SmartRTL
4	SmartRTL or Hold
5	Terminate

Critical battery failsafe action (BATT_FS_CRT_ACT)

What action the vehicle should perform if it hits a critical battery failsafe

Value	Meaning
0	None
1	RTL
2	Hold
3	SmartRTL
4	SmartRTL or Hold
5	Terminate

Required arming voltage (BATT_ARM_VOLT)

Battery voltage level which is required to arm the aircraft. Set to 0 to allow arming at any voltage.

• Units: volt
• Increment: 0.1

Required arming remaining capacity (BATT_ARM_MAH)

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.

• Units: milliampere hour
• Increment: 50

Battery monitor options (BATT_OPTIONS)

This sets options to change the behaviour of the battery monitor

• Bitmask: 0:Ignore DroneCAN SoC, 1:MPPT reports input voltage and current, 2:MPPT Powered off when disarmed, 3:MPPT Powered on when armed, 4:MPPT Powered off at boot, 5:MPPT Powered on at boot, 6:Send resistance compensated voltage to GCS

Battery Voltage sensing pin (BATT_VOLT_PIN)

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

• RebootRequired: True

Battery Current sensing pin (BATT_CURR_PIN)

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

• RebootRequired: True

Voltage Multiplier (BATT_VOLT_MULT)

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.

Amps per volt (BATT_AMP_PERVLT)

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.

• Units: ampere per volt

AMP offset (BATT_AMP_OFFSET)

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.

• Units: volt

Voltage offset (BATT_VLT_OFFSET)

Voltage offset on voltage pin. This allows for an offset due to a diode. This voltage is subtracted before the scaling is applied.

• Units: volt

Battery monitor I2C bus number (BATT_I2C_BUS)

Battery monitor I2C bus number

• Range: 0 3
• RebootRequired: True

Battery monitor I2C address (BATT_I2C_ADDR)

Battery monitor I2C address

• Range: 0 127
• RebootRequired: True

Battery Sum mask (BATT_SUM_MASK)

0: sum of remaining battery monitors, If none 0 sum of specified monitors. Current will be summed and voltages averaged.

• Bitmask: 0:monitor 1, 1:monitor 2, 2:monitor 3, 3:monitor 4, 4:monitor 5, 5:monitor 6, 6:monitor 7, 7:monitor 8, 8:monitor 9

Scales reported power monitor current (BATT_CURR_MULT)

Multiplier applied to all current related reports to allow for adjustment if no UAVCAN param access or current splitting applications

• Range: .1 10

Empty fuel level voltage (BATT_FL_VLT_MIN)

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.

• Range: 0.01 10
• Units: volt

Fuel level voltage multiplier (BATT_FL_V_MULT)

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.

• Range: 0.01 10

Fuel level filter frequency (BATT_FL_FLTR)

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.

• Range: -1 1
• Units: hertz
• RebootRequired: True

Fuel level analog pin number (BATT_FL_PIN)

Analog input pin that fuel level sensor is connected to. Airspeed ports can be used for Analog input. When using analog pin 103, the maximum value of the input in 3.3V.

Value	Meaning
-1	Not Used
11	Pixracer
13	Pixhawk ADC4
14	Pixhawk ADC3
15	Pixhawk ADC6/Pixhawk2 ADC
103	Pixhawk SBUS

Maximum Battery Voltage (BATT_MAX_VOLT)

Maximum voltage of battery. Provides scaling of current versus voltage

• Range: 7 100

BCN Parameters

Beacon based position estimation device type (BCN_TYPE)

What type of beacon based position estimation device is connected

Value	Meaning
0	None
1	Pozyx
2	Marvelmind
3	Nooploop
10	SITL

Beacon origin's latitude (BCN_LATITUDE)

Beacon origin's latitude

• Units: degrees
• Increment: 0.000001
• Range: -90 90

Beacon origin's longitude (BCN_LONGITUDE)

Beacon origin's longitude

• Units: degrees
• Increment: 0.000001
• Range: -180 180

Beacon origin's altitude above sealevel in meters (BCN_ALT)

Beacon origin's altitude above sealevel in meters

• Units: meters
• Increment: 1
• Range: 0 10000

Beacon systems rotation from north in degrees (BCN_ORIENT_YAW)

Beacon systems rotation from north in degrees

• Units: degrees
• Increment: 1
• Range: -180 +180

BRD_ Parameters

Serial 1 flow control (BRD_SER1_RTSCTS)

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

• RebootRequired: True

Serial 2 flow control (BRD_SER2_RTSCTS)

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

• RebootRequired: True

Serial 3 flow control (BRD_SER3_RTSCTS)

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

• RebootRequired: True

Serial 4 flow control (BRD_SER4_RTSCTS)

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

• RebootRequired: True

Serial 5 flow control (BRD_SER5_RTSCTS)

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

• RebootRequired: True

Sets default state of the safety switch (BRD_SAFETY_DEFLT)

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

• RebootRequired: True

SBUS output rate (BRD_SBUS_OUT)

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

• RebootRequired: True

User-defined serial number (BRD_SERIAL_NUM)

User-defined serial number of this vehicle, it can be any arbitrary number you want and has no effect on the autopilot

• Range: -8388608 8388607

Outputs which ignore the safety switch state (BRD_SAFETY_MASK)

A bitmask which controls what outputs can move while the safety switch has not been pressed

• Bitmask: 0:Output1,1:Output2,2:Output3,3:Output4,4:Output5,5:Output6,6:Output7,7:Output8,8:Output9,9:Output10,10:Output11,11:Output12,12:Output13,13:Output14
• RebootRequired: True

Board heater temperature target (BRD_HEAT_TARG)

Board heater target temperature for boards with controllable heating units. DO NOT SET to -1 on the Cube. Set to -1 to disable the heater, please reboot after setting to -1.

• Range: -1 80
• Units: degrees Celsius

Board type (BRD_TYPE)

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
4	Pixracer
5	PixhawkMini
6	Pixhawk2Slim
13	Intel Aero FC
14	Pixhawk Pro
20	AUAV2.1
21	PCNC1
22	MINDPXV2
23	SP01
24	CUAVv5/FMUV5
30	VRX BRAIN51
32	VRX BRAIN52
33	VRX BRAIN52E
34	VRX UBRAIN51
35	VRX UBRAIN52
36	VRX CORE10
38	VRX BRAIN54
39	PX4 FMUV6
100	PX4 OLDDRIVERS

• RebootRequired: True

Enable IO co-processor (BRD_IO_ENABLE)

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

• RebootRequired: True

Options for safety button behavior (BRD_SAFETYOPTION)

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

• Bitmask: 0:ActiveForSafetyDisable,1:ActiveForSafetyEnable,2:ActiveWhenArmed,3:Force safety on when the aircraft disarms

Autopilot board voltage requirement (BRD_VBUS_MIN)

Minimum voltage on the autopilot power rail to allow the aircraft to arm. 0 to disable the check.

• Units: volt
• Range: 4.0 5.5
• Increment: 0.1

Servo voltage requirement (BRD_VSERVO_MIN)

Minimum voltage on the servo rail to allow the aircraft to arm. 0 to disable the check.

• Units: volt
• Range: 3.3 12.0
• Increment: 0.1

microSD slowdown (BRD_SD_SLOWDOWN)

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.

• Range: 0 32
• Increment: 1

Set PWM Out Voltage (BRD_PWM_VOLT_SEL)

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 auxilliary 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 options (BRD_OPTIONS)

Board specific option flags

• Bitmask: 0:Enable hardware watchdog, 1:Disable MAVftp, 2:Enable set of internal parameters, 3:Enable Debug Pins, 4:Unlock flash on reboot, 5:Write protect firmware flash on reboot, 6:Write protect bootloader flash on reboot

Boot delay (BRD_BOOT_DELAY)

This adds a delay in milliseconds to boot to ensure peripherals initialise fully

• Range: 0 10000
• Units: milliseconds

Board Heater P gain (BRD_HEAT_P)

Board Heater P gain

• Range: 1 500
• Increment: 1

Board Heater I gain (BRD_HEAT_I)

Board Heater integrator gain

• Range: 0 1
• Increment: 0.1

Board Heater IMAX (BRD_HEAT_IMAX)

Board Heater integrator maximum

• Range: 0 100
• Increment: 1

Alternative HW config (BRD_ALT_CONFIG)

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.

• Range: 0 10
• Increment: 1
• RebootRequired: True

Board heater temp lower margin (BRD_HEAT_LOWMGN)

Arming check will fail if temp is lower than this margin below BRD_HEAT_TARG. 0 disables the low temperature check

• Range: 0 20
• Units: degrees Celsius

SDCard Mission size (BRD_SD_MISSION)

This sets the amount of storage in kilobytes reserved on the microsd card in mission.stg for waypoint storage. Each waypoint uses 15 bytes.

• Range: 0 64
• RebootRequired: True

BRD_RADIO Parameters

Set type of direct attached radio (BRD_RADIO_TYPE)

This enables support for direct attached radio receivers

Value	Meaning
0	None
1	CYRF6936
2	CC2500
3	BK2425

protocol (BRD_RADIO_PROT)

Select air protocol

Value	Meaning
0	Auto
1	DSM2
2	DSMX

debug level (BRD_RADIO_DEBUG)

radio debug level

• Range: 0 4

disable receive CRC (BRD_RADIO_DISCRC)

disable receive CRC (for debug)

Value	Meaning
0	NotDisabled
1	Disabled

RSSI signal strength (BRD_RADIO_SIGCH)

Channel to show receive RSSI signal strength, or zero for disabled

• Range: 0 16

Packet rate channel (BRD_RADIO_PPSCH)

Channel to show received packet-per-second rate, or zero for disabled

• Range: 0 16

Enable telemetry (BRD_RADIO_TELEM)

If this is non-zero then telemetry packets will be sent over DSM

Value	Meaning
0	Disabled
1	Enabled

Telemetry Transmit power (BRD_RADIO_TXPOW)

Set telemetry transmit power. This is the power level (from 1 to 8) for telemetry packets sent from the RX to the TX

• Range: 1 8

Put radio into FCC test mode (BRD_RADIO_FCCTST)

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

Stick input mode (BRD_RADIO_STKMD)

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

Set radio to factory test channel (BRD_RADIO_TESTCH)

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

RSSI value channel for telemetry data on transmitter (BRD_RADIO_TSIGCH)

Channel to show telemetry RSSI value as received by TX

• Range: 0 16

Telemetry PPS channel (BRD_RADIO_TPPSCH)

Channel to show telemetry packets-per-second value, as received at TX

• Range: 0 16

Transmitter transmit power (BRD_RADIO_TXMAX)

Set transmitter maximum transmit power (from 1 to 8)

• Range: 1 8

Transmitter buzzer adjustment (BRD_RADIO_BZOFS)

Set transmitter buzzer note adjustment (adjust frequency up)

• Range: 0 40

Auto-bind time (BRD_RADIO_ABTIME)

When non-zero this sets the time with no transmitter packets before we start looking for auto-bind packets.

• Range: 0 120

Auto-bind level (BRD_RADIO_ABLVL)

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

• Range: 0 31

BRD_RTC Parameters

Allowed sources of RTC time (BRD_RTC_TYPES)

Specifies which sources of UTC time will be accepted

• Bitmask: 0:GPS,1:MAVLINK_SYSTEM_TIME,2:HW

Timezone offset from UTC (BRD_RTC_TZ_MIN)

Adds offset in +- minutes from UTC to calculate local time

• Range: -720 +840

BTN_ Parameters

Enable button reporting (BTN_ENABLE)

This enables the button checking module. When this is disabled the parameters for setting button inputs are not visible

Value	Meaning
0	Disabled
1	Enabled

First button Pin (BTN_PIN1)

Digital pin number for first button input. 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	AUXOUT1
51	AUXOUT2
52	AUXOUT3
53	AUXOUT4
54	AUXOUT5
55	AUXOUT6

Second button Pin (BTN_PIN2)

Digital pin number for second button input. 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	AUXOUT1
51	AUXOUT2
52	AUXOUT3
53	AUXOUT4
54	AUXOUT5
55	AUXOUT6

Third button Pin (BTN_PIN3)

Digital pin number for third button input. 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	AUXOUT1
51	AUXOUT2
52	AUXOUT3
53	AUXOUT4
54	AUXOUT5
55	AUXOUT6

Fourth button Pin (BTN_PIN4)

Digital pin number for fourth button input. 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	AUXOUT1
51	AUXOUT2
52	AUXOUT3
53	AUXOUT4
54	AUXOUT5
55	AUXOUT6

Report send time (BTN_REPORT_SEND)

The duration in seconds that a BUTTON_CHANGE report is repeatedly sent to the GCS regarding a button changing state. Note that the BUTTON_CHANGE message is MAVLink2 only.

• Range: 0 3600

Button Pin 1 Options (BTN_OPTIONS1)

Options for Pin 1. PWM input detects PWM above or below 1800/1200us instead of logic level. If PWM is not detected or is less than 800us or above 2200us the button will interpreted as low. Invert changes HIGH state to be logic low voltage on pin, or below 1200us, if PWM input.

• Bitmask: 0:PWM Input,1:InvertInput

Button Pin 2 Options (BTN_OPTIONS2)

Options for Pin 2. PWM input detects PWM above or below 1800/1200us instead of logic level. If PWM is not detected or is less than 800us or above 2200us the button will interpreted as low. Invert changes HIGH state to be logic low voltage on pin, or below 1200us, if PWM input.

• Bitmask: 0:PWM Input,1:InvertInput

Button Pin 3 Options (BTN_OPTIONS3)

Options for Pin 3. PWM input detects PWM above or below 1800/1200us instead of logic level. If PWM is not detected or is less than 800us or above 2200us the button will interpreted as low. Invert changes HIGH state to be logic low voltage on pin, or below 1200us, if PWM input.

• Bitmask: 0:PWM Input,1:InvertInput

Button Pin 4 Options (BTN_OPTIONS4)

Options for Pin 4. PWM input detects PWM above or below 1800/1200us instead of logic level. If PWM is not detected or is less than 800us or above 2200us the button will interpreted as low. Invert changes HIGH state to be logic low voltage on pin, or below 1200us, if PWM input.

• Bitmask: 0:PWM Input,1:InvertInput

Button Pin 1 RC Channel function (BTN_FUNC1)

Auxiliary RC Options function executed on pin change

Value	Meaning
0	Do Nothing
4	RTL
5	Save Trim (4.1 and lower)
7	Save WP
9	Camera Trigger
11	Fence
16	Auto
19	Gripper
24	Auto Mission Reset
27	Retract Mount1
28	Relay On/Off
30	Lost Rover Sound
31	Motor Emergency Stop
34	Relay2 On/Off
35	Relay3 On/Off
36	Relay4 On/Off
40	Proximity Avoidance
41	ArmDisarm (4.1 and lower)
42	SmartRTL
46	RC Override Enable
50	LearnCruise
51	Manual
52	Acro
53	Steering
54	Hold
55	Guided
56	Loiter
57	Follow
58	Clear Waypoints
59	Simple Mode
62	Compass Learn
63	Sailboat Tack
65	GPS Disable
66	Relay5 On/Off
67	Relay6 On/Off
74	Sailboat motoring 3pos
78	RunCam Control
79	RunCam OSD Control
80	Viso Align
81	Disarm
90	EKF Pos Source
94	VTX Power
97	Windvane home heading direction offset
100	KillIMU1
101	KillIMU2
102	Camera Mode Toggle
105	GPS Disable Yaw
106	Disable Airspeed Use
110	KillIMU3
153	ArmDisarm (4.2 and higher)
155	set steering trim to current servo and RC
156	Torqeedo Clear Err
162	FFT Tune
163	Mount Lock
164	Pause Stream Logging
165	Arm/Emergency Motor Stop
166	Camera Record Video
167	Camera Zoom
168	Camera Manual Focus
169	Camera Auto Focus
171	Calibrate Compasses
172	Battery MPPT Enable
201	Roll
202	Pitch
207	MainSail
208	Flap
211	Walking Height
212	Mount1 Roll
213	Mount1 Pitch
214	Mount1 Yaw
215	Mount2 Roll
216	Mount2 Pitch
217	Mount2 Yaw
300	Scripting1
301	Scripting2
302	Scripting3
303	Scripting4
304	Scripting5
305	Scripting6
306	Scripting7
307	Scripting8

Button Pin 2 RC Channel function (BTN_FUNC2)

Auxiliary RC Options function executed on pin change

Value	Meaning
0	Do Nothing
4	RTL
5	Save Trim (4.1 and lower)
7	Save WP
9	Camera Trigger
11	Fence
16	Auto
19	Gripper
24	Auto Mission Reset
27	Retract Mount1
28	Relay On/Off
30	Lost Rover Sound
31	Motor Emergency Stop
34	Relay2 On/Off
35	Relay3 On/Off
36	Relay4 On/Off
40	Proximity Avoidance
41	ArmDisarm (4.1 and lower)
42	SmartRTL
46	RC Override Enable
50	LearnCruise
51	Manual
52	Acro
53	Steering
54	Hold
55	Guided
56	Loiter
57	Follow
58	Clear Waypoints
59	Simple Mode
62	Compass Learn
63	Sailboat Tack
65	GPS Disable
66	Relay5 On/Off
67	Relay6 On/Off
74	Sailboat motoring 3pos
78	RunCam Control
79	RunCam OSD Control
80	Viso Align
81	Disarm
90	EKF Pos Source
94	VTX Power
97	Windvane home heading direction offset
100	KillIMU1
101	KillIMU2
102	Camera Mode Toggle
105	GPS Disable Yaw
106	Disable Airspeed Use
110	KillIMU3
153	ArmDisarm (4.2 and higher)
155	set steering trim to current servo and RC
156	Torqeedo Clear Err
162	FFT Tune
163	Mount Lock
164	Pause Stream Logging
165	Arm/Emergency Motor Stop
166	Camera Record Video
167	Camera Zoom
168	Camera Manual Focus
169	Camera Auto Focus
171	Calibrate Compasses
172	Battery MPPT Enable
201	Roll
202	Pitch
207	MainSail
208	Flap
211	Walking Height
212	Mount1 Roll
213	Mount1 Pitch
214	Mount1 Yaw
215	Mount2 Roll
216	Mount2 Pitch
217	Mount2 Yaw
300	Scripting1
301	Scripting2
302	Scripting3
303	Scripting4
304	Scripting5
305	Scripting6
306	Scripting7
307	Scripting8

Button Pin 3 RC Channel function (BTN_FUNC3)

Auxiliary RC Options function executed on pin change

Value	Meaning
0	Do Nothing
4	RTL
5	Save Trim (4.1 and lower)
7	Save WP
9	Camera Trigger
11	Fence
16	Auto
19	Gripper
24	Auto Mission Reset
27	Retract Mount1
28	Relay On/Off
30	Lost Rover Sound
31	Motor Emergency Stop
34	Relay2 On/Off
35	Relay3 On/Off
36	Relay4 On/Off
40	Proximity Avoidance
41	ArmDisarm (4.1 and lower)
42	SmartRTL
46	RC Override Enable
50	LearnCruise
51	Manual
52	Acro
53	Steering
54	Hold
55	Guided
56	Loiter
57	Follow
58	Clear Waypoints
59	Simple Mode
62	Compass Learn
63	Sailboat Tack
65	GPS Disable
66	Relay5 On/Off
67	Relay6 On/Off
74	Sailboat motoring 3pos
78	RunCam Control
79	RunCam OSD Control
80	Viso Align
81	Disarm
90	EKF Pos Source
94	VTX Power
97	Windvane home heading direction offset
100	KillIMU1
101	KillIMU2
102	Camera Mode Toggle
105	GPS Disable Yaw
106	Disable Airspeed Use
110	KillIMU3
153	ArmDisarm (4.2 and higher)
155	set steering trim to current servo and RC
156	Torqeedo Clear Err
162	FFT Tune
163	Mount Lock
164	Pause Stream Logging
165	Arm/Emergency Motor Stop
166	Camera Record Video
167	Camera Zoom
168	Camera Manual Focus
169	Camera Auto Focus
171	Calibrate Compasses
172	Battery MPPT Enable
201	Roll
202	Pitch
207	MainSail
208	Flap
211	Walking Height
212	Mount1 Roll
213	Mount1 Pitch
214	Mount1 Yaw
215	Mount2 Roll
216	Mount2 Pitch
217	Mount2 Yaw
300	Scripting1
301	Scripting2
302	Scripting3
303	Scripting4
304	Scripting5
305	Scripting6
306	Scripting7
307	Scripting8

Button Pin 4 RC Channel function (BTN_FUNC4)

Auxiliary RC Options function executed on pin change

Value	Meaning
0	Do Nothing
4	RTL
5	Save Trim (4.1 and lower)
7	Save WP
9	Camera Trigger
11	Fence
16	Auto
19	Gripper
24	Auto Mission Reset
27	Retract Mount1
28	Relay On/Off
30	Lost Rover Sound
31	Motor Emergency Stop
34	Relay2 On/Off
35	Relay3 On/Off
36	Relay4 On/Off
40	Proximity Avoidance
41	ArmDisarm (4.1 and lower)
42	SmartRTL
46	RC Override Enable
50	LearnCruise
51	Manual
52	Acro
53	Steering
54	Hold
55	Guided
56	Loiter
57	Follow
58	Clear Waypoints
59	Simple Mode
62	Compass Learn
63	Sailboat Tack
65	GPS Disable
66	Relay5 On/Off
67	Relay6 On/Off
74	Sailboat motoring 3pos
78	RunCam Control
79	RunCam OSD Control
80	Viso Align
81	Disarm
90	EKF Pos Source
94	VTX Power
97	Windvane home heading direction offset
100	KillIMU1
101	KillIMU2
102	Camera Mode Toggle
105	GPS Disable Yaw
106	Disable Airspeed Use
110	KillIMU3
153	ArmDisarm (4.2 and higher)
155	set steering trim to current servo and RC
156	Torqeedo Clear Err
162	FFT Tune
163	Mount Lock
164	Pause Stream Logging
165	Arm/Emergency Motor Stop
166	Camera Record Video
167	Camera Zoom
168	Camera Manual Focus
169	Camera Auto Focus
171	Calibrate Compasses
172	Battery MPPT Enable
201	Roll
202	Pitch
207	MainSail
208	Flap
211	Walking Height
212	Mount1 Roll
213	Mount1 Pitch
214	Mount1 Yaw
215	Mount2 Roll
216	Mount2 Pitch
217	Mount2 Yaw
300	Scripting1
301	Scripting2
302	Scripting3
303	Scripting4
304	Scripting5
305	Scripting6
306	Scripting7
307	Scripting8