Difference between revisions of "Rotorcraft Configuration"

From PaparazziUAV
Jump to: navigation, search
(add motor arming info)
m (Motor Arming)
Line 84: Line 84:
  
 
== Motor Arming ==
 
== Motor Arming ==
By default the motors are armed with zero-throttle and full yaw. You need to be in manual mode to start the motors via RC.
+
By default the motors are armed with zero-throttle and full yaw. The motors are never started if AHRS is not aligned (disable it with AUTOPILOT_DISABLE_AHRS_KILL).
The motors are never started if AHRS is not aligned (disable it with AUTOPILOT_DISABLE_AHRS_KILL).
 
  
 
Other arming sequences can be configured:
 
Other arming sequences can be configured:
Line 92: Line 91:
 
** if kill switch is off during startup, you need to kill again first, then unkill to start
 
** if kill switch is off during startup, you need to kill again first, then unkill to start
 
** throttle needs to be down, other sticks centered to start motors
 
** throttle needs to be down, other sticks centered to start motors
 +
** need to be in manual mode to start the motors
  
 
* USE_THROTTLE_FOR_MOTOR_ARMING defined (to 1):
 
* USE_THROTTLE_FOR_MOTOR_ARMING defined (to 1):
Line 97: Line 97:
 
** if throttle was not down at startup, you need to put throttle down again first
 
** if throttle was not down at startup, you need to put throttle down again first
 
** other sticks need to be centered to start motors
 
** other sticks need to be centered to start motors
 +
** need to be in manual mode to start the motors
  
 
== Autopilot modes ==
 
== Autopilot modes ==

Revision as of 02:51, 20 September 2012

This page describes configuration options specific to the rotorcraft firmware in the airframe file.

The airframe configuration file is located in conf/airframes and contains all the hardware and software settings for an aircraft. All gains, trims, and behavior settings are defined with standard XML elements. Optionally you can also add a raw Makefile section.

Firmware and Hardware definitions

This is one example of a pretty standard quadcopter firmware definition:

File: conf/airframes/myplane.xml
  <firmware name="rotorcraft">
    <target name="nps" board="pc">
      <subsystem name="fdm"   type="jsbsim"/>
    </target>
    <target name="ap" board="lisa_m_1.0"/>

    <subsystem name="radio_control" type="ppm"/>
    <subsystem name="telemetry"     type="transparent"/>
    <subsystem name="actuators"     type="mkk"/>
    <subsystem name="imu"           type="aspirin_v1.5"/>
    <subsystem name="gps"           type="ublox"/>
    <subsystem name="ahrs"          type="int_cmpl_quat"/>
    <subsystem name="stabilization" type="int_quat"/>
  </firmware>

Select your Board

The airframe file must include the description of the controller board and it's low-level settings. This is done in the firmware section by specifying the board attribute for the target "ap" (autopilot).

Select the appropriate board: "pc", "twog_1.0", "tiny_2.11", "tiny_2.1", "tiny_1.1", "tiny_0.99", "booz_1.0", "lisa_l_1.0", "lisa_l_1.1", "lisa_m_1.0", "lisa_m_2.0", "navgo_1.0", "umarim_1.0"

File: conf/airframes/myplane.xml
  <firmware name="rotorcraft">
    <target name="ap"   board="booz_1.0"/>
     ...
  </firmware>

Actuators

You have to specify which ESCs you have by adding the appropriate actuators subsystem.

File: conf/airframes/myplane.xml
  <firmware name="rotorcraft">
    <target name="ap" board="booz_1.0"/>
     ...
    <subsystem name="actuators" type="mkk"/>
  </firmware>

Control Loops

See the stabilization subsystem page to choose which attitude control algorithm to use and how to configure them.

The Control Loops page has some diagrams.

INS

The optional INS (Integrated Navigation System) subsystem contains estimations filter to e.g. fuse GPS and IMU data for better position and speed estimates.

File: conf/airframes/myplane.xml
  <firmware name="rotorcraft">
    <target name="ap" board="booz_1.0"/>
     ...
    <subsystem name="ins" type="hff"/>
  </firmware>

You can also compensate for GPS lag in hff (horizontal filter float) if it is known (in seconds):

File: conf/airframes/myplane.xml
  <firmware name="rotorcraft">
    <target name="ap" board="booz_1.0"/>
     ...
    <subsystem name="ins" type="hff">
      <define name="GPS_LAG=0.2"/>
    </subsystem>
  </firmware>

Motor Arming

By default the motors are armed with zero-throttle and full yaw. The motors are never started if AHRS is not aligned (disable it with AUTOPILOT_DISABLE_AHRS_KILL).

Other arming sequences can be configured:

  • USE_KILL_SWITCH_FOR_MOTOR_ARMING defined (to 1):
    • switch kill switch off to arm the motors
    • if kill switch is off during startup, you need to kill again first, then unkill to start
    • throttle needs to be down, other sticks centered to start motors
    • need to be in manual mode to start the motors
  • USE_THROTTLE_FOR_MOTOR_ARMING defined (to 1):
    • automatically start motors when applying throttle
    • if throttle was not down at startup, you need to put throttle down again first
    • other sticks need to be centered to start motors
    • need to be in manual mode to start the motors

Autopilot modes

For rotorcrafts we have a lot of different modes that can be mapped to your 3-position switch (Manual, Auto1, Auto2). The horizontal and vertical mode can be set differently as the following possible modes indicate (in parenthesis are the abbreviations displayed in the GCS strip) :

AP_MODE_FAILSAFE (SAFE) 

This is a failsafe mode that gets triggered if:

  • RC signal is lost (and you are not in KILL or NAV mode)
  • GPS and RC is lost in NAV mode

The autopilot will level the rotorcraft out (setpoints to zero pitch and roll angles) and descend at 0.5m/s downwards.

AP_MODE_KILL (KILL) 

Motors are simply switched off.

AP_MODE_RATE_DIRECT (RATE) 

This is basically the "most" manual mode you can get. You control not the attitude (roll and pitch angles) but the rotation rate. You also set the throttle directly with your RC.

AP_MODE_ATTITUDE_DIRECT (ATT) 

You control the attitude (roll, pitch and yaw angles), but the throttle directly proportional to your stick position.

AP_MODE_RATE_RC_CLIMB (R_RCC) 

You control the rotation rate and the vertical speed according to your throttle stick position. If you have your throttle stick in the middle position, the altitude is kept, down goes down at a speed proportional to your stick position (same for up). In this mode it makes sense to mount the spring for your throttle stick so it can recenter itself.

AP_MODE_ATTITUDE_RC_CLIMB (A_RCC) 

You control the attitude (roll, pitch and yaw angles) and the vertical speed according to your throttle stick position. If you have your throttle stick in the middle position the altitude is kept, if you move the stick down it goes down at a speed proportional to your stick position (same for up). In this mode it makes sense to mount the spring for your throttle stick so it recenter itself.

AP_MODE_ATTITUDE_CLIMB (ATT_C) 

You control the attitude (roll, pitch and yaw angles) and the vertical speed. The vertical speed is set via fms (e.g. joystick).

AP_MODE_RATE_Z_HOLD (R_ZH) 

You control the rotation rate and it holds the altitude you were at when entering this mode. Your throttle stick position still limits the max throttle authority, so you should push your throttle stick up after entering this mode so the vertical controller has some "room" to stabilize the altitude. Should something weird happen you can limit the max thrust by taking throttle back.

AP_MODE_ATTITUDE_Z_HOLD (A_ZH) 

You control the attitude (roll, pitch and yaw angles) and it holds the altitude you were at when entering this mode. Your throttle stick position still limits the max throttle authority, so you should push your throttle stick up after entering this mode so the vertical controller has some "room" to stabilize the altitude. Should something weird happen you can limit the max thrust by taking throttle back.

AP_MODE_HOVER_DIRECT (HOVER) 

The rotorcraft hovers at the horizontal position you were at when entering this mode (position control). You still set the throttle directly with your RC.

AP_MODE_HOVER_CLIMB (HOV_C) 

The rotorcraft hovers at the position you were at when entering this mode (position control). The vertical speed is set via fms (e.g. joystick).

AP_MODE_HOVER_Z_HOLD (H_ZH)

The rotorcraft hovers at the 3D position you were at when entering this mode (position and altitude control). Your throttle stick position still limits the max throttle authority, so you should push your throttle stick up after entering this mode so the vertical controller has some "room" to stabilize the altitude. Should something weird happen you can limit the max thrust by taking throttle back.

AP_MODE_NAV (NAV) 

Full navigation mode. The rotorcraft follows your flightplan.

AP_MODE_RC_DIRECT (RC_D) 

Safety pilot direct commands for helicopter.

XML Parameters

Mode

In the mode section you can set the autopilot modes associated with your 3-way mode switch on your RC.

  <section name="MODE" prefix="MODE_">
    <define name="MANUAL" value="AP_MODE_ATTITUDE_DIRECT" />
    <define name="AUTO1" value="AP_MODE_ATTITUDE_Z_HOLD" />
    <define name="AUTO2" value="AP_MODE_HOVER_Z_HOLD" />
  </section>

Commands

The commands lists the abstract commands you need to control the aircraft. For most multicopter you just need:

  <commands>
    <axis name="PITCH" failsafe_value="0"/>
    <axis name="ROLL" failsafe_value="0"/>
    <axis name="YAW" failsafe_value="0 />
    <axis name="THRUST" failsafe_value="0"/>
  </commands>

Each command is also associated with a failsafe value which will be used if no controller is active, for example during initialization of the autopilot board.

Supervision

This section describes the "mixing" used for your particular multirotor configuration. This section is needed for "mkk" (mikrokopter), "pwm_supervision" and "asctecV2" controllers, as "asctecV1" do their mixing themselves.

  <section name="SUPERVISION" prefix="SUPERVISION_">
    <define name="STOP_MOTOR" value="0"/> <!-- this defaults to zero, set to a different value if needed, e.g. for pwm controllers -->
    <define name="MIN_MOTOR" value="3"/>
    <define name="MAX_MOTOR" value="200"/>
    <define name="TRIM_A" value="0"/>
    <define name="TRIM_E" value="0"/>
    <define name="TRIM_R" value="0"/>
    <define name="NB_MOTOR" value="4"/>
    <define name="SCALE" value="256"/>
    <define name="ROLL_COEF"   value="{  0  ,    0,  256, -256 }"/>
    <define name="PITCH_COEF"  value="{  256, -256,    0,    0 }"/>
    <define name="YAW_COEF"    value="{ -256, -256,  256,  256 }"/>
    <define name="THRUST_COEF" value="{  256,  256,  256,  256 }"/>
  </section>
STOP_MOTOR 
actuator specific command value to stop the motors
MIN_MOTOR 
actuator specific command value for idling motors
MAX_MOTOR 
actuator specific command value for maximum power
TRIM_A 
trim added to roll command
TRIM_E 
trim added to pitch command
TRIM_R 
trim added to yaw command
x_COEF 
roll/pitch/yaw/thrust coefficients, see RotorcraftMixing for details or the examples below

If your rotors are spinning opposite to the direction shown in the picture, just reverse signs in the YAW_COEF line.

Plus Cross 
Cross plus simple.png

Assuming that the order of motors, described in the "servos" section is FRONT, BACK, LEFT, RIGHT.

    <define name="ROLL_COEF"   value="{    0,    0,  256, -256 }"/>
    <define name="PITCH_COEF"  value="{  256, -256,    0,    0 }"/>
    <define name="YAW_COEF"    value="{ -256, -256,  256,  256 }"/>
    <define name="THRUST_COEF" value="{  256,  256,  256,  256 }"/>


Time Cross 
Cross time simple.png

Assuming that the order of motors, described in the "servos" section is NE, SE, SW, NW.

    <define name="ROLL_COEF"   value="{ -256, -256,  256,  256 }"/>
    <define name="PITCH_COEF"  value="{  256, -256, -256,  256 }"/>
    <define name="YAW_COEF"    value="{ -256,  256, -256,  256 }"/>
    <define name="THRUST_COEF" value="{  256,  256,  256,  256 }"/>


Octo (time cross)
Octo.jpg
    <define name="ROLL_COEF"   value="{  106, -106, -256, -256, -106,  106,  256,  256 }"/>
    <define name="PITCH_COEF"  value="{  256,  256,  106, -106, -256, -256, -106,  106 }"/>
    <define name="YAW_COEF"    value="{ -256,  256, -256,  256, -256,  256, -256,  256 }"/>
    <define name="THRUST_COEF" value="{  256,  256,  256,  256,  256,  256,  256,  256 }"/>


Octo (plus cross)
rotor 1 on x-axis (image anyone?)
    <define name="ROLL_COEF"   value="{    0, -181, -256, -181,    0,  181,  256,  181 }"/>
    <define name="PITCH_COEF"  value="{  256,  181,    0, -181, -256, -181,    0,  181 }"/>
    <define name="YAW_COEF"    value="{ -256,  256, -256,  256, -256,  256, -256,  256 }"/>
    <define name="THRUST_COEF" value="{  256,  256,  256,  256,  256,  256,  256,  256 }"/>


If you want to compute mixing for a special configuration, please see the RotorcraftMixing page.

Simulation

Values from this section can be used to tweak the SITL simulation. The NPS (New Paparazzi Sim) currently uses JSBSim as for the flight dynamic modeling, but other FDMs are possible.

  <section name="SIMULATOR" prefix="NPS_">
    <define name="ACTUATOR_NAMES" value="{&quot;front_motor&quot;, &quot;back_motor&quot;, &quot;right_motor&quot;, &quot;left_motor&quot;}" />
    <define name="INITIAL_CONDITITONS" value="&quot;reset00&quot;" />
    <define name="SENSORS_PARAMS" value="&quot;nps_sensors_params_booz2_a1.h&quot;" />
  </section>