Update PX4 Firmware metadata Tue Jan 19 14:22:49 UTC 2021

4 years ago · 3a21902e91
2 changed files with 535 additions and 0 deletions
--- a/src/AutoPilotPlugins/PX4/AirframeFactMetaData.xml
+++ b/src/AutoPilotPlugins/PX4/AirframeFactMetaData.xml
@ -141,6 +141,11 @@
      <output name="AUX1">feed-through of RC AUX1 channel</output>
      <output name="AUX2">feed-through of RC AUX2 channel</output>
    </airframe>
    <airframe name="Hex X with control allocation" id="6003" maintainer="Silvan Fuhrer">
      <class>Copter</class>
      <maintainer>Silvan Fuhrer</maintainer>
      <type>Hexarotor x</type>
    </airframe>
  </airframe_group>
  <airframe_group name="Octo Coax Wide" image="OctoRotorXCoaxial">
    <airframe name="Steadidrone MAVRIK" id="12002" maintainer="Simon Wilks &lt;simon@uaventure.com&gt;">
@ -384,6 +389,11 @@
      <output name="MAIN3">motor 3</output>
      <output name="MAIN4">motor 4</output>
    </airframe>
    <airframe name="S500 with control allocation" id="4018" maintainer="Silvan Fuhrer">
      <class>Copter</class>
      <maintainer>Silvan Fuhrer</maintainer>
      <type>Quadrotor x</type>
    </airframe>
    <airframe name="Hobbyking Micro PCB" id="4020" maintainer="Thomas Gubler &lt;thomas@px4.io&gt;">
      <class>Copter</class>
      <maintainer>Thomas Gubler &lt;thomas@px4.io&gt;</maintainer>
--- a/src/FirmwarePlugin/PX4/PX4ParameterFactMetaData.xml
+++ b/src/FirmwarePlugin/PX4/PX4ParameterFactMetaData.xml
@ -306,6 +306,153 @@
      <unit>m/s^2</unit>
    </parameter>
  </group>
  <group name="Angular Velocity Control">
    <parameter name="AVC_X_D" default="0.36" type="FLOAT">
      <short_desc>Body X axis angular velocity D gain</short_desc>
      <long_desc>Body X axis angular velocity differential gain. Small values help reduce fast oscillations. If value is too big oscillations will appear again.</long_desc>
      <min>0.0</min>
      <max>2.0</max>
      <decimal>4</decimal>
      <increment>0.01</increment>
    </parameter>
    <parameter name="AVC_X_FF" default="0.0" type="FLOAT">
      <short_desc>Body X axis angular velocity feedforward gain</short_desc>
      <long_desc>Improves tracking performance.</long_desc>
      <min>0.0</min>
      <unit>Nm/(rad/s)</unit>
      <decimal>4</decimal>
    </parameter>
    <parameter name="AVC_X_I" default="0.2" type="FLOAT">
      <short_desc>Body X axis angular velocity I gain</short_desc>
      <long_desc>Body X axis angular velocity integral gain. Can be set to compensate static thrust difference or gravity center offset.</long_desc>
      <min>0.0</min>
      <unit>Nm/rad</unit>
      <decimal>3</decimal>
      <increment>0.01</increment>
    </parameter>
    <parameter name="AVC_X_I_LIM" default="0.3" type="FLOAT">
      <short_desc>Body X axis angular velocity integrator limit</short_desc>
      <long_desc>Body X axis angular velocity integrator limit. Can be set to increase the amount of integrator available to counteract disturbances or reduced to improve settling time after large roll moment trim changes.</long_desc>
      <min>0.0</min>
      <unit>Nm</unit>
      <decimal>2</decimal>
      <increment>0.01</increment>
    </parameter>
    <parameter name="AVC_X_K" default="1.0" type="FLOAT">
      <short_desc>Body X axis angular velocity controller gain</short_desc>
      <long_desc>Global gain of the controller. This gain scales the P, I and D terms of the controller: output = AVC_X_K * (AVC_X_P * error + AVC_X_I * error_integral + AVC_X_D * error_derivative) Set AVC_X_P=1 to implement a PID in the ideal form. Set AVC_X_K=1 to implement a PID in the parallel form.</long_desc>
      <min>0.0</min>
      <max>5.0</max>
      <decimal>4</decimal>
      <increment>0.0005</increment>
    </parameter>
    <parameter name="AVC_X_P" default="18." type="FLOAT">
      <short_desc>Body X axis angular velocity P gain</short_desc>
      <long_desc>Body X axis angular velocity proportional gain, i.e. control output for angular speed error 1 rad/s.</long_desc>
      <min>0.0</min>
      <max>20.0</max>
      <unit>1/s</unit>
      <decimal>3</decimal>
      <increment>0.01</increment>
    </parameter>
    <parameter name="AVC_Y_D" default="0.36" type="FLOAT">
      <short_desc>Body Y axis angular velocity D gain</short_desc>
      <long_desc>Body Y axis angular velocity differential gain. Small values help reduce fast oscillations. If value is too big oscillations will appear again.</long_desc>
      <min>0.0</min>
      <max>2.0</max>
      <decimal>4</decimal>
      <increment>0.01</increment>
    </parameter>
    <parameter name="AVC_Y_FF" default="0.0" type="FLOAT">
      <short_desc>Body Y axis angular velocity feedforward</short_desc>
      <long_desc>Improves tracking performance.</long_desc>
      <min>0.0</min>
      <unit>Nm/(rad/s)</unit>
      <decimal>4</decimal>
    </parameter>
    <parameter name="AVC_Y_I" default="0.2" type="FLOAT">
      <short_desc>Body Y axis angular velocity I gain</short_desc>
      <long_desc>Body Y axis angular velocity integral gain. Can be set to compensate static thrust difference or gravity center offset.</long_desc>
      <min>0.0</min>
      <unit>Nm/rad</unit>
      <decimal>3</decimal>
      <increment>0.01</increment>
    </parameter>
    <parameter name="AVC_Y_I_LIM" default="0.3" type="FLOAT">
      <short_desc>Body Y axis angular velocity integrator limit</short_desc>
      <long_desc>Body Y axis angular velocity integrator limit. Can be set to increase the amount of integrator available to counteract disturbances or reduced to improve settling time after large pitch moment trim changes.</long_desc>
      <min>0.0</min>
      <unit>Nm</unit>
      <decimal>2</decimal>
      <increment>0.01</increment>
    </parameter>
    <parameter name="AVC_Y_K" default="1.0" type="FLOAT">
      <short_desc>Body Y axis angular velocity controller gain</short_desc>
      <long_desc>Global gain of the controller. This gain scales the P, I and D terms of the controller: output = AVC_Y_K * (AVC_Y_P * error + AVC_Y_I * error_integral + AVC_Y_D * error_derivative) Set AVC_Y_P=1 to implement a PID in the ideal form. Set AVC_Y_K=1 to implement a PID in the parallel form.</long_desc>
      <min>0.0</min>
      <max>20.0</max>
      <decimal>4</decimal>
      <increment>0.0005</increment>
    </parameter>
    <parameter name="AVC_Y_P" default="18." type="FLOAT">
      <short_desc>Body Y axis angular velocity P gain</short_desc>
      <long_desc>Body Y axis angular velocity proportional gain, i.e. control output for angular speed error 1 rad/s.</long_desc>
      <min>0.0</min>
      <max>20.0</max>
      <unit>1/s</unit>
      <decimal>3</decimal>
      <increment>0.01</increment>
    </parameter>
    <parameter name="AVC_Z_D" default="0.0" type="FLOAT">
      <short_desc>Body Z axis angular velocity D gain</short_desc>
      <long_desc>Body Z axis angular velocity differential gain. Small values help reduce fast oscillations. If value is too big oscillations will appear again.</long_desc>
      <min>0.0</min>
      <max>2.0</max>
      <decimal>2</decimal>
      <increment>0.01</increment>
    </parameter>
    <parameter name="AVC_Z_FF" default="0.0" type="FLOAT">
      <short_desc>Body Z axis angular velocity feedforward</short_desc>
      <long_desc>Improves tracking performance.</long_desc>
      <min>0.0</min>
      <unit>Nm/(rad/s)</unit>
      <decimal>4</decimal>
      <increment>0.01</increment>
    </parameter>
    <parameter name="AVC_Z_I" default="0.1" type="FLOAT">
      <short_desc>Body Z axis angular velocity I gain</short_desc>
      <long_desc>Body Z axis angular velocity integral gain. Can be set to compensate static thrust difference or gravity center offset.</long_desc>
      <min>0.0</min>
      <unit>Nm/rad</unit>
      <decimal>2</decimal>
      <increment>0.01</increment>
    </parameter>
    <parameter name="AVC_Z_I_LIM" default="0.30" type="FLOAT">
      <short_desc>Body Z axis angular velocity integrator limit</short_desc>
      <long_desc>Body Z axis angular velocity integrator limit. Can be set to increase the amount of integrator available to counteract disturbances or reduced to improve settling time after large yaw moment trim changes.</long_desc>
      <min>0.0</min>
      <unit>Nm</unit>
      <decimal>2</decimal>
      <increment>0.01</increment>
    </parameter>
    <parameter name="AVC_Z_K" default="1.0" type="FLOAT">
      <short_desc>Body Z axis angular velocity controller gain</short_desc>
      <long_desc>Global gain of the controller. This gain scales the P, I and D terms of the controller: output = AVC_Z_K * (AVC_Z_P * error + AVC_Z_I * error_integral + AVC_Z_D * error_derivative) Set AVC_Z_P=1 to implement a PID in the ideal form. Set AVC_Z_K=1 to implement a PID in the parallel form.</long_desc>
      <min>0.0</min>
      <max>5.0</max>
      <decimal>4</decimal>
      <increment>0.0005</increment>
    </parameter>
    <parameter name="AVC_Z_P" default="7." type="FLOAT">
      <short_desc>Body Z axis angular velocity P gain</short_desc>
      <long_desc>Body Z axis angular velocity proportional gain, i.e. control output for angular speed error 1 rad/s.</long_desc>
      <min>0.0</min>
      <max>20.0</max>
      <unit>1/s</unit>
      <decimal>2</decimal>
      <increment>0.01</increment>
    </parameter>
  </group>
  <group name="Attitude Q estimator">
    <parameter name="ATT_ACC_COMP" default="1" type="INT32">
      <short_desc>Acceleration compensation based on GPS
@ -1404,6 +1551,340 @@ See COM_OBL_ACT and COM_OBL_RC_ACT to configure action</short_desc>
      <unit>min</unit>
    </parameter>
  </group>
  <group name="Control Allocation">
    <parameter name="CA_ACT0_MAX" default="0.0" type="FLOAT">
      <short_desc>Maximum value for actuator 0</short_desc>
    </parameter>
    <parameter name="CA_ACT0_MIN" default="0.0" type="FLOAT">
      <short_desc>Minimum value for actuator 0</short_desc>
    </parameter>
    <parameter name="CA_ACT10_MAX" default="0.0" type="FLOAT">
      <short_desc>Maximum value for actuator 10</short_desc>
    </parameter>
    <parameter name="CA_ACT10_MIN" default="0.0" type="FLOAT">
      <short_desc>Minimum value for actuator 10</short_desc>
    </parameter>
    <parameter name="CA_ACT11_MAX" default="0.0" type="FLOAT">
      <short_desc>Maximum value for actuator 11</short_desc>
    </parameter>
    <parameter name="CA_ACT11_MIN" default="0.0" type="FLOAT">
      <short_desc>Minimum value for actuator 11</short_desc>
    </parameter>
    <parameter name="CA_ACT12_MAX" default="0.0" type="FLOAT">
      <short_desc>Maximum value for actuator 12</short_desc>
    </parameter>
    <parameter name="CA_ACT12_MIN" default="0.0" type="FLOAT">
      <short_desc>Minimum value for actuator 12</short_desc>
    </parameter>
    <parameter name="CA_ACT13_MAX" default="0.0" type="FLOAT">
      <short_desc>Maximum value for actuator 13</short_desc>
    </parameter>
    <parameter name="CA_ACT13_MIN" default="0.0" type="FLOAT">
      <short_desc>Minimum value for actuator 13</short_desc>
    </parameter>
    <parameter name="CA_ACT14_MAX" default="0.0" type="FLOAT">
      <short_desc>Maximum value for actuator 14</short_desc>
    </parameter>
    <parameter name="CA_ACT14_MIN" default="0.0" type="FLOAT">
      <short_desc>Minimum value for actuator 14</short_desc>
    </parameter>
    <parameter name="CA_ACT15_MAX" default="0.0" type="FLOAT">
      <short_desc>Maximum value for actuator 15</short_desc>
    </parameter>
    <parameter name="CA_ACT15_MIN" default="0.0" type="FLOAT">
      <short_desc>Minimum value for actuator 15</short_desc>
    </parameter>
    <parameter name="CA_ACT1_MAX" default="0.0" type="FLOAT">
      <short_desc>Maximum value for actuator 1</short_desc>
    </parameter>
    <parameter name="CA_ACT1_MIN" default="0.0" type="FLOAT">
      <short_desc>Minimum value for actuator 1</short_desc>
    </parameter>
    <parameter name="CA_ACT2_MAX" default="0.0" type="FLOAT">
      <short_desc>Maximum value for actuator 2</short_desc>
    </parameter>
    <parameter name="CA_ACT2_MIN" default="0.0" type="FLOAT">
      <short_desc>Minimum value for actuator 2</short_desc>
    </parameter>
    <parameter name="CA_ACT3_MAX" default="0.0" type="FLOAT">
      <short_desc>Maximum value for actuator 3</short_desc>
    </parameter>
    <parameter name="CA_ACT3_MIN" default="0.0" type="FLOAT">
      <short_desc>Minimum value for actuator 3</short_desc>
    </parameter>
    <parameter name="CA_ACT4_MAX" default="0.0" type="FLOAT">
      <short_desc>Maximum value for actuator 4</short_desc>
    </parameter>
    <parameter name="CA_ACT4_MIN" default="0.0" type="FLOAT">
      <short_desc>Minimum value for actuator 4</short_desc>
    </parameter>
    <parameter name="CA_ACT5_MAX" default="0.0" type="FLOAT">
      <short_desc>Maximum value for actuator 5</short_desc>
    </parameter>
    <parameter name="CA_ACT5_MIN" default="0.0" type="FLOAT">
      <short_desc>Minimum value for actuator 5</short_desc>
    </parameter>
    <parameter name="CA_ACT6_MAX" default="0.0" type="FLOAT">
      <short_desc>Maximum value for actuator 6</short_desc>
    </parameter>
    <parameter name="CA_ACT6_MIN" default="0.0" type="FLOAT">
      <short_desc>Minimum value for actuator 6</short_desc>
    </parameter>
    <parameter name="CA_ACT7_MAX" default="0.0" type="FLOAT">
      <short_desc>Maximum value for actuator 7</short_desc>
    </parameter>
    <parameter name="CA_ACT7_MIN" default="0.0" type="FLOAT">
      <short_desc>Minimum value for actuator 7</short_desc>
    </parameter>
    <parameter name="CA_ACT8_MAX" default="0.0" type="FLOAT">
      <short_desc>Maximum value for actuator 8</short_desc>
    </parameter>
    <parameter name="CA_ACT8_MIN" default="0.0" type="FLOAT">
      <short_desc>Minimum value for actuator 8</short_desc>
    </parameter>
    <parameter name="CA_ACT9_MAX" default="0.0" type="FLOAT">
      <short_desc>Maximum value for actuator 9</short_desc>
    </parameter>
    <parameter name="CA_ACT9_MIN" default="0.0" type="FLOAT">
      <short_desc>Minimum value for actuator 9</short_desc>
    </parameter>
    <parameter name="CA_AIRFRAME" default="0" type="INT32">
      <short_desc>Airframe ID</short_desc>
      <long_desc>This is used to retrieve pre-computed control effectiveness matrix</long_desc>
      <min>0</min>
      <max>2</max>
      <values>
        <value code="0">Multirotor</value>
        <value code="1">Standard VTOL (WIP)</value>
        <value code="2">Tiltrotor VTOL (WIP)</value>
      </values>
    </parameter>
    <parameter name="CA_AIR_SCALE_EN" default="0" type="INT32">
      <short_desc>Airspeed scaler</short_desc>
      <long_desc>This compensates for the variation of flap effectiveness with airspeed.</long_desc>
    </parameter>
    <parameter name="CA_BAT_SCALE_EN" default="0" type="INT32">
      <short_desc>Battery power level scaler</short_desc>
      <long_desc>This compensates for voltage drop of the battery over time by attempting to normalize performance across the operating range of the battery. The copter should constantly behave as if it was fully charged with reduced max acceleration at lower battery percentages. i.e. if hover is at 0.5 throttle at 100% battery, it will still be 0.5 at 60% battery.</long_desc>
    </parameter>
    <parameter name="CA_MC_R0_AX" default="0.0" type="FLOAT">
      <short_desc>Axis of rotor 0 thrust vector, X body axis component</short_desc>
    </parameter>
    <parameter name="CA_MC_R0_AY" default="0.0" type="FLOAT">
      <short_desc>Axis of rotor 0 thrust vector, Y body axis component</short_desc>
    </parameter>
    <parameter name="CA_MC_R0_AZ" default="-1.0" type="FLOAT">
      <short_desc>Axis of rotor 0 thrust vector, Z body axis component</short_desc>
    </parameter>
    <parameter name="CA_MC_R0_CT" default="0.0" type="FLOAT">
      <short_desc>Thrust coefficient of rotor 0</short_desc>
      <long_desc>The thrust coefficient if defined as Thrust = CT * u^2, where u (with value between CA_ACT0_MIN and CA_ACT0_MAX) is the output signal sent to the motor controller.</long_desc>
    </parameter>
    <parameter name="CA_MC_R0_KM" default="0.05" type="FLOAT">
      <short_desc>Moment coefficient of rotor 0</short_desc>
      <long_desc>The moment coefficient if defined as Torque = KM * Thrust Use a positive value for a rotor with CCW rotation. Use a negative value for a rotor with CW rotation.</long_desc>
    </parameter>
    <parameter name="CA_MC_R0_PX" default="0.0" type="FLOAT">
      <short_desc>Position of rotor 0 along X body axis</short_desc>
    </parameter>
    <parameter name="CA_MC_R0_PY" default="0.0" type="FLOAT">
      <short_desc>Position of rotor 0 along Y body axis</short_desc>
    </parameter>
    <parameter name="CA_MC_R0_PZ" default="0.0" type="FLOAT">
      <short_desc>Position of rotor 0 along Z body axis</short_desc>
    </parameter>
    <parameter name="CA_MC_R1_AX" default="0.0" type="FLOAT">
      <short_desc>Axis of rotor 1 thrust vector, X body axis component</short_desc>
    </parameter>
    <parameter name="CA_MC_R1_AY" default="0.0" type="FLOAT">
      <short_desc>Axis of rotor 1 thrust vector, Y body axis component</short_desc>
    </parameter>
    <parameter name="CA_MC_R1_AZ" default="-1.0" type="FLOAT">
      <short_desc>Axis of rotor 1 thrust vector, Z body axis component</short_desc>
    </parameter>
    <parameter name="CA_MC_R1_CT" default="0.0" type="FLOAT">
      <short_desc>Thrust coefficient of rotor 1</short_desc>
      <long_desc>The thrust coefficient if defined as Thrust = CT * u^2, where u (with value between CA_ACT1_MIN and CA_ACT1_MAX) is the output signal sent to the motor controller.</long_desc>
    </parameter>
    <parameter name="CA_MC_R1_KM" default="0.05" type="FLOAT">
      <short_desc>Moment coefficient of rotor 1</short_desc>
      <long_desc>The moment coefficient if defined as Torque = KM * Thrust, Use a positive value for a rotor with CCW rotation. Use a negative value for a rotor with CW rotation.</long_desc>
    </parameter>
    <parameter name="CA_MC_R1_PX" default="0.0" type="FLOAT">
      <short_desc>Position of rotor 1 along X body axis</short_desc>
    </parameter>
    <parameter name="CA_MC_R1_PY" default="0.0" type="FLOAT">
      <short_desc>Position of rotor 1 along Y body axis</short_desc>
    </parameter>
    <parameter name="CA_MC_R1_PZ" default="0.0" type="FLOAT">
      <short_desc>Position of rotor 1 along Z body axis</short_desc>
    </parameter>
    <parameter name="CA_MC_R2_AX" default="0.0" type="FLOAT">
      <short_desc>Axis of rotor 2 thrust vector, X body axis component</short_desc>
    </parameter>
    <parameter name="CA_MC_R2_AY" default="0.0" type="FLOAT">
      <short_desc>Axis of rotor 2 thrust vector, Y body axis component</short_desc>
    </parameter>
    <parameter name="CA_MC_R2_AZ" default="-1.0" type="FLOAT">
      <short_desc>Axis of rotor 2 thrust vector, Z body axis component</short_desc>
    </parameter>
    <parameter name="CA_MC_R2_CT" default="0.0" type="FLOAT">
      <short_desc>Thrust coefficient of rotor 2</short_desc>
      <long_desc>The thrust coefficient if defined as Thrust = CT * u^2, where u (with value between CA_ACT2_MIN and CA_ACT2_MAX) is the output signal sent to the motor controller.</long_desc>
    </parameter>
    <parameter name="CA_MC_R2_KM" default="0.05" type="FLOAT">
      <short_desc>Moment coefficient of rotor 2</short_desc>
      <long_desc>The moment coefficient if defined as Torque = KM * Thrust Use a positive value for a rotor with CCW rotation. Use a negative value for a rotor with CW rotation.</long_desc>
    </parameter>
    <parameter name="CA_MC_R2_PX" default="0.0" type="FLOAT">
      <short_desc>Position of rotor 2 along X body axis</short_desc>
    </parameter>
    <parameter name="CA_MC_R2_PY" default="0.0" type="FLOAT">
      <short_desc>Position of rotor 2 along Y body axis</short_desc>
    </parameter>
    <parameter name="CA_MC_R2_PZ" default="0.0" type="FLOAT">
      <short_desc>Position of rotor 2 along Z body axis</short_desc>
    </parameter>
    <parameter name="CA_MC_R3_AX" default="0.0" type="FLOAT">
      <short_desc>Axis of rotor 3 thrust vector, X body axis component</short_desc>
    </parameter>
    <parameter name="CA_MC_R3_AY" default="0.0" type="FLOAT">
      <short_desc>Axis of rotor 3 thrust vector, Y body axis component</short_desc>
    </parameter>
    <parameter name="CA_MC_R3_AZ" default="-1.0" type="FLOAT">
      <short_desc>Axis of rotor 3 thrust vector, Z body axis component</short_desc>
    </parameter>
    <parameter name="CA_MC_R3_CT" default="0.0" type="FLOAT">
      <short_desc>Thrust coefficient of rotor 3</short_desc>
      <long_desc>The thrust coefficient if defined as Thrust = CT * u^2, where u (with value between CA_ACT3_MIN and CA_ACT3_MAX) is the output signal sent to the motor controller.</long_desc>
    </parameter>
    <parameter name="CA_MC_R3_KM" default="0.05" type="FLOAT">
      <short_desc>Moment coefficient of rotor 3</short_desc>
      <long_desc>The moment coefficient if defined as Torque = KM * Thrust Use a positive value for a rotor with CCW rotation. Use a negative value for a rotor with CW rotation.</long_desc>
    </parameter>
    <parameter name="CA_MC_R3_PX" default="0.0" type="FLOAT">
      <short_desc>Position of rotor 3 along X body axis</short_desc>
    </parameter>
    <parameter name="CA_MC_R3_PY" default="0.0" type="FLOAT">
      <short_desc>Position of rotor 3 along Y body axis</short_desc>
    </parameter>
    <parameter name="CA_MC_R3_PZ" default="0.0" type="FLOAT">
      <short_desc>Position of rotor 3 along Z body axis</short_desc>
    </parameter>
    <parameter name="CA_MC_R4_AX" default="0.0" type="FLOAT">
      <short_desc>Axis of rotor 4 thrust vector, X body axis component</short_desc>
    </parameter>
    <parameter name="CA_MC_R4_AY" default="0.0" type="FLOAT">
      <short_desc>Axis of rotor 4 thrust vector, Y body axis component</short_desc>
    </parameter>
    <parameter name="CA_MC_R4_AZ" default="-1.0" type="FLOAT">
      <short_desc>Axis of rotor 4 thrust vector, Z body axis component</short_desc>
    </parameter>
    <parameter name="CA_MC_R4_CT" default="0.0" type="FLOAT">
      <short_desc>Thrust coefficient of rotor 4</short_desc>
      <long_desc>The thrust coefficient if defined as Thrust = CT * u^2, where u (with value between CA_ACT4_MIN and CA_ACT4_MAX) is the output signal sent to the motor controller.</long_desc>
    </parameter>
    <parameter name="CA_MC_R4_KM" default="0.05" type="FLOAT">
      <short_desc>Moment coefficient of rotor 4</short_desc>
      <long_desc>The moment coefficient if defined as Torque = KM * Thrust Use a positive value for a rotor with CCW rotation. Use a negative value for a rotor with CW rotation.</long_desc>
    </parameter>
    <parameter name="CA_MC_R4_PX" default="0.0" type="FLOAT">
      <short_desc>Position of rotor 4 along X body axis</short_desc>
    </parameter>
    <parameter name="CA_MC_R4_PY" default="0.0" type="FLOAT">
      <short_desc>Position of rotor 4 along Y body axis</short_desc>
    </parameter>
    <parameter name="CA_MC_R4_PZ" default="0.0" type="FLOAT">
      <short_desc>Position of rotor 4 along Z body axis</short_desc>
    </parameter>
    <parameter name="CA_MC_R5_AX" default="0.0" type="FLOAT">
      <short_desc>Axis of rotor 5 thrust vector, X body axis component</short_desc>
    </parameter>
    <parameter name="CA_MC_R5_AY" default="0.0" type="FLOAT">
      <short_desc>Axis of rotor 5 thrust vector, Y body axis component</short_desc>
    </parameter>
    <parameter name="CA_MC_R5_AZ" default="-1.0" type="FLOAT">
      <short_desc>Axis of rotor 5 thrust vector, Z body axis component</short_desc>
    </parameter>
    <parameter name="CA_MC_R5_CT" default="0.0" type="FLOAT">
      <short_desc>Thrust coefficient of rotor 5</short_desc>
      <long_desc>The thrust coefficient if defined as Thrust = CT * u^2, where u (with value between CA_ACT5_MIN and CA_ACT5_MAX) is the output signal sent to the motor controller.</long_desc>
    </parameter>
    <parameter name="CA_MC_R5_KM" default="0.05" type="FLOAT">
      <short_desc>Moment coefficient of rotor 5</short_desc>
      <long_desc>The moment coefficient if defined as Torque = KM * Thrust Use a positive value for a rotor with CCW rotation. Use a negative value for a rotor with CW rotation.</long_desc>
    </parameter>
    <parameter name="CA_MC_R5_PX" default="0.0" type="FLOAT">
      <short_desc>Position of rotor 5 along X body axis</short_desc>
    </parameter>
    <parameter name="CA_MC_R5_PY" default="0.0" type="FLOAT">
      <short_desc>Position of rotor 5 along Y body axis</short_desc>
    </parameter>
    <parameter name="CA_MC_R5_PZ" default="0.0" type="FLOAT">
      <short_desc>Position of rotor 5 along Z body axis</short_desc>
    </parameter>
    <parameter name="CA_MC_R6_AX" default="0.0" type="FLOAT">
      <short_desc>Axis of rotor 6 thrust vector, X body axis component</short_desc>
    </parameter>
    <parameter name="CA_MC_R6_AY" default="0.0" type="FLOAT">
      <short_desc>Axis of rotor 6 thrust vector, Y body axis component</short_desc>
    </parameter>
    <parameter name="CA_MC_R6_AZ" default="-1.0" type="FLOAT">
      <short_desc>Axis of rotor 6 thrust vector, Z body axis component</short_desc>
    </parameter>
    <parameter name="CA_MC_R6_CT" default="0.0" type="FLOAT">
      <short_desc>Thrust coefficient of rotor 6</short_desc>
      <long_desc>The thrust coefficient if defined as Thrust = CT * u^2, where u (with value between CA_ACT6_MIN and CA_ACT6_MAX) is the output signal sent to the motor controller.</long_desc>
    </parameter>
    <parameter name="CA_MC_R6_KM" default="0.05" type="FLOAT">
      <short_desc>Moment coefficient of rotor 6</short_desc>
      <long_desc>The moment coefficient if defined as Torque = KM * Thrust Use a positive value for a rotor with CCW rotation. Use a negative value for a rotor with CW rotation.</long_desc>
    </parameter>
    <parameter name="CA_MC_R6_PX" default="0.0" type="FLOAT">
      <short_desc>Position of rotor 6 along X body axis</short_desc>
    </parameter>
    <parameter name="CA_MC_R6_PY" default="0.0" type="FLOAT">
      <short_desc>Position of rotor 6 along Y body axis</short_desc>
    </parameter>
    <parameter name="CA_MC_R6_PZ" default="0.0" type="FLOAT">
      <short_desc>Position of rotor 6 along Z body axis</short_desc>
    </parameter>
    <parameter name="CA_MC_R7_AX" default="0.0" type="FLOAT">
      <short_desc>Axis of rotor 7 thrust vector, X body axis component</short_desc>
    </parameter>
    <parameter name="CA_MC_R7_AY" default="0.0" type="FLOAT">
      <short_desc>Axis of rotor 7 thrust vector, Y body axis component</short_desc>
    </parameter>
    <parameter name="CA_MC_R7_AZ" default="-1.0" type="FLOAT">
      <short_desc>Axis of rotor 7 thrust vector, Z body axis component</short_desc>
    </parameter>
    <parameter name="CA_MC_R7_CT" default="0.0" type="FLOAT">
      <short_desc>Thrust coefficient of rotor 7</short_desc>
      <long_desc>The thrust coefficient if defined as Thrust = CT * u^2, where u (with value between CA_ACT7_MIN and CA_ACT7_MAX) is the output signal sent to the motor controller.</long_desc>
    </parameter>
    <parameter name="CA_MC_R7_KM" default="0.05" type="FLOAT">
      <short_desc>Moment coefficient of rotor 7</short_desc>
      <long_desc>The moment coefficient if defined as Torque = KM * Thrust Use a positive value for a rotor with CCW rotation. Use a negative value for a rotor with CW rotation.</long_desc>
    </parameter>
    <parameter name="CA_MC_R7_PX" default="0.0" type="FLOAT">
      <short_desc>Position of rotor 7 along X body axis</short_desc>
    </parameter>
    <parameter name="CA_MC_R7_PY" default="0.0" type="FLOAT">
      <short_desc>Position of rotor 7 along Y body axis</short_desc>
    </parameter>
    <parameter name="CA_MC_R7_PZ" default="0.0" type="FLOAT">
      <short_desc>Position of rotor 7 along Z body axis</short_desc>
    </parameter>
    <parameter name="CA_METHOD" default="0" type="INT32">
      <short_desc>Control allocation method</short_desc>
      <min>0</min>
      <max>1</max>
      <values>
        <value code="0">Pseudo-inverse with output clipping (default)</value>
        <value code="1">Pseudo-inverse with sequential desaturation technique</value>
      </values>
    </parameter>
  </group>
  <group name="DShot">
    <parameter name="DSHOT_CONFIG" default="0" type="INT32">
      <short_desc>Configure DShot</short_desc>
@ -12402,6 +12883,50 @@ to fixed wing mode. Zero or negative values will produce an instant throttle ris
      <increment>0.01</increment>
    </parameter>
  </group>
  <group name="Vehicle Model">
    <parameter name="VM_INERTIA_XX" default="0.01" type="FLOAT">
      <short_desc>Inertia matrix, XX component</short_desc>
      <unit>kg m^2</unit>
      <decimal>5</decimal>
      <increment>0.00001</increment>
    </parameter>
    <parameter name="VM_INERTIA_XY" default="0." type="FLOAT">
      <short_desc>Inertia matrix, XY component</short_desc>
      <unit>kg m^2</unit>
      <decimal>5</decimal>
      <increment>0.00001</increment>
    </parameter>
    <parameter name="VM_INERTIA_XZ" default="0." type="FLOAT">
      <short_desc>Inertia matrix, XZ component</short_desc>
      <unit>kg m^2</unit>
      <decimal>5</decimal>
      <increment>0.00001</increment>
    </parameter>
    <parameter name="VM_INERTIA_YY" default="0.01" type="FLOAT">
      <short_desc>Inertia matrix, YY component</short_desc>
      <unit>kg m^2</unit>
      <decimal>5</decimal>
      <increment>0.00001</increment>
    </parameter>
    <parameter name="VM_INERTIA_YZ" default="0." type="FLOAT">
      <short_desc>Inertia matrix, YZ component</short_desc>
      <unit>kg m^2</unit>
      <decimal>5</decimal>
      <increment>0.00001</increment>
    </parameter>
    <parameter name="VM_INERTIA_ZZ" default="0.01" type="FLOAT">
      <short_desc>Inertia matrix, ZZ component</short_desc>
      <unit>kg m^2</unit>
      <decimal>5</decimal>
      <increment>0.00001</increment>
    </parameter>
    <parameter name="VM_MASS" default="1." type="FLOAT">
      <short_desc>Mass</short_desc>
      <unit>kg</unit>
      <decimal>5</decimal>
      <increment>0.00001</increment>
    </parameter>
  </group>
  <group name="Miscellaneous">
    <parameter name="EXFW_HDNG_P" default="0.1" type="FLOAT">
      <short_desc>EXFW_HDNG_P</short_desc>