// CONFIG FILE FOR APM_Rover project by Jean-Louis Naudin // #define GCS_PORT 3 #define GCS_PROTOCOL GCS_PROTOCOL_MAVLINK // QGroundControl protocol //#define GCS_PROTOCOL GCS_PROTOCOL_NONE // No GCS protocol to save memory #define HIL_MODE HIL_MODE_DISABLED #define MAV_SYSTEM_ID 1 // Add a ground start delay in seconds //#define GROUND_START_DELAY 1 #define AIRSPEED_SENSOR DISABLED #define SONAR_ENABLED DISABLED #define SONAR_TRIGGER 200 // trigger distance in cm #if LITE == DISABLED #define MAGNETOMETER ENABLED #define LOGGING_ENABLED ENABLED #define MAG_ORIENTATION AP_COMPASS_COMPONENTS_UP_PINS_FORWARD #define PARAM_DECLINATION 0.18 // Paris #endif ////////////////////////////////////////////////////////////////////////////// // Serial port speeds. // #define SERIAL0_BAUD 115200 #define SERIAL3_BAUD 115200 ////////////////////////////////////////////////////////////////////////////// // GPS_PROTOCOL #define GPS_PROTOCOL GPS_PROTOCOL_AUTO #define CH7_OPTION CH7_SAVE_WP #define TUNING_OPTION TUN_NONE #define FLIGHT_MODE_1 AUTO // pos 0 --- #define FLIGHT_MODE_2 AUTO // pos 1 #define FLIGHT_MODE_3 STABILIZE // pos 2 #define FLIGHT_MODE_4 STABILIZE // pos 3 --- #define FLIGHT_MODE_5 MANUAL // pos 4 #define FLIGHT_MODE_6 MANUAL // pos 5 --- #define ENABLE_AIR_START DISABLED #define MANUAL_LEVEL DISABLED #define TURN_GAIN 5 #define CLOSED_LOOP_NAV ENABLED // set to ENABLED if closed loop navigation else set to DISABLED (Return To Lauch) #define AUTO_WP_RADIUS DISABLED #define MAX_DIST 50 //300 // max distance (in m) for the HEADALT mode #define SARSEC_BRANCH 50 // Long branch of the SARSEC pattern ////////////////////////////////////////////////////////////////////////////// ////////////////////////////////////////////////////////////////////////////// // FLIGHT AND NAVIGATION CONTROL ////////////////////////////////////////////////////////////////////////////// ////////////////////////////////////////////////////////////////////////////// // AIRSPEED_CRUISE OPTIONAL // // The speed in metres per second to maintain during cruise. The default // is 10m/s, which is a conservative value suitable for relatively small, // light aircraft. // #define AIRSPEED_CRUISE 3 #define GSBOOST 0 #define NUDGE_OFFSET 0 #define MIN_GNDSPEED 3 ////////////////////////////////////////////////////////////////////////////// // FLY_BY_WIRE_B airspeed control (also used for throttle "nudging" in AUTO) // // AIRSPEED_FBW_MIN OPTIONAL // AIRSPEED_FBW_MAX OPTIONAL // // Airspeed corresponding to minimum and maximum throttle in Fly By Wire B mode. // The defaults are 6 and 30 metres per second. // // AIRSPEED_FBW_MAX also sets the maximum airspeed that the cruise airspeed can be "nudged" to in AUTO mode when ENABLE_STICK_MIXING is set. // In AUTO the cruise airspeed can be increased between AIRSPEED_CRUISE and AIRSPEED_FBW_MAX by positioning the throttle // stick in the top 1/2 of its range. Throttle stick in the bottom 1/2 provide regular AUTO control. // #define AIRSPEED_FBW_MIN 6 #define AIRSPEED_FBW_MAX 35 // ////////////////////////////////////////////////////////////////////////////// // Servo mapping // // THROTTLE_MIN OPTIONAL // // The minimum throttle setting to which the autopilot will reduce the // throttle while descending. The default is zero, which is // suitable for aircraft with a steady power-off glide. Increase this // value if your aircraft needs throttle to maintain a stable descent in // level flight. // // THROTTLE_CRUISE OPTIONAL // // The approximate throttle setting to achieve AIRSPEED_CRUISE in level flight. // The default is 45%, which is reasonable for a modestly powered aircraft. // // THROTTLE_MAX OPTIONAL // // The maximum throttle setting the autopilot will apply. The default is 75%. // Reduce this value if your aicraft is overpowered, or has complex flight // characteristics at high throttle settings. // #define THROTTLE_MIN 0 // percent #define THROTTLE_CRUISE 3 // 40 #define THROTTLE_MAX 100 ////////////////////////////////////////////////////////////////////////////// // AUTO_TRIM OPTIONAL // // ArduPilot Mega can update its trim settings by looking at the // radio inputs when switching out of MANUAL mode. This allows you to // manually trim your aircraft before switching to an assisted mode, but it // also means that you should avoid switching out of MANUAL while you have // any control stick deflection. // // The default is to enable AUTO_TRIM. // #define AUTO_TRIM ENABLED #define THROTTLE_FAILSAFE DISABLED //#define ENABLE_AIR_START 0 ////////////////////////////////////////////////////////////////////////////// // Autopilot control limits // // HEAD_MAX OPTIONAL // // The maximum commanded bank angle in either direction. // The default is 45 degrees. Decrease this value if your aircraft is not // stable or has difficulty maintaining altitude in a steep bank. // // PITCH_MAX OPTIONAL // // The maximum commanded pitch up angle. // The default is 15 degrees. Care should be taken not to set this value too // large, as the aircraft may stall. // // PITCH_MIN // // The maximum commanded pitch down angle. Note that this value must be // negative. The default is -25 degrees. Care should be taken not to set // this value too large as it may result in overspeeding the aircraft. // // PITCH_TARGET // // The target pitch for cruise flight. When the APM measures this pitch // value, the pitch error will be calculated to be 0 for the pitch PID // control loop. // #define HEAD_MAX 80 #define PITCH_MAX 15 #define PITCH_MIN -20 //-25 #define PITCH_TARGET 0 ////////////////////////////////////////////////////////////////////////////// // Attitude control gains // // Tuning values for the attitude control PID loops. // // The P term is the primary tuning value. This determines how the control // deflection varies in proportion to the required correction. // // The I term is used to help control surfaces settle. This value should // normally be kept low. // // The D term is used to control overshoot. Avoid using or adjusting this // term if you are not familiar with tuning PID loops. It should normally // be zero for most aircraft. // // Note: When tuning these values, start with changes of no more than 25% at // a time. // // SERVO_ROLL_P OPTIONAL // SERVO_ROLL_I OPTIONAL // SERVO_ROLL_D OPTIONAL // // P, I and D terms for roll control. Defaults are 0.4, 0, 0. // // SERVO_ROLL_INT_MAX OPTIONAL // // Maximum control offset due to the integral. This prevents the control // output from being overdriven due to a persistent offset (e.g. crosstracking). // Default is 5 degrees. // // ROLL_SLEW_LIMIT EXPERIMENTAL // // Limits the slew rate of the roll control in degrees per second. If zero, // slew rate is not limited. Default is to not limit the roll control slew rate. // (This feature is currently not implemented.) // // SERVO_PITCH_P OPTIONAL // SERVO_PITCH_I OPTIONAL // SERVO_PITCH_D OPTIONAL // // P, I and D terms for the pitch control. Defaults are 0.6, 0, 0. // // SERVO_PITCH_INT_MAX OPTIONAL // // Maximum control offset due to the integral. This prevents the control // output from being overdriven due to a persistent offset (e.g. native flight // AoA). If you find this value is insufficient, consider adjusting the AOA // parameter. // Default is 5 degrees. // // PITCH_COMP OPTIONAL // // Adds pitch input to compensate for the loss of lift due to roll control. // Default is 0.20 (20% of roll control also applied to pitch control). // // SERVO_YAW_P OPTIONAL // SERVO_YAW_I OPTIONAL // SERVO_YAW_D OPTIONAL // // P, I and D terms for the YAW control. Defaults are 0., 0., 0. // Note units of this control loop are unusual. PID input is in m/s**2. // // SERVO_YAW_INT_MAX OPTIONAL // // Maximum control offset due to the integral. This prevents the control // output from being overdriven due to a persistent offset (e.g. crosstracking). // Default is 0. // // RUDDER_MIX OPTIONAL // // Roll to yaw mixing. This allows for co-ordinated turns. // Default is 0.50 (50% of roll control also applied to yaw control.) // #define SERVO_ROLL_P 0.0 #define SERVO_ROLL_I 0.0 #define SERVO_ROLL_D 0.0 #define SERVO_ROLL_INT_MAX 5 #define ROLL_SLEW_LIMIT 0 #define SERVO_PITCH_P 0.0 #define SERVO_PITCH_I 0.0 #define SERVO_PITCH_D 0.0 #define SERVO_PITCH_INT_MAX 5 #define PITCH_COMP 0.0 #define SERVO_YAW_P 0.0 // Default is zero. A suggested value if you want to use this parameter is 0.5 #define SERVO_YAW_I 0.0 #define SERVO_YAW_D 0.0 #define SERVO_YAW_INT_MAX 5 #define RUDDER_MIX 0.0 // ////////////////////////////////////////////////////////////////////////////// // Navigation control gains // // Tuning values for the navigation control PID loops. // // The P term is the primary tuning value. This determines how the control // deflection varies in proportion to the required correction. // // The I term is used to control drift. // // The D term is used to control overshoot. Avoid adjusting this term if // you are not familiar with tuning PID loops. // // Note: When tuning these values, start with changes of no more than 25% at // a time. // // NAV_ROLL_P OPTIONAL // NAV_ROLL_I OPTIONAL // NAV_ROLL_D OPTIONAL // // P, I and D terms for navigation control over roll, normally used for // controlling the aircraft's course. The P term controls how aggressively // the aircraft will bank to change or hold course. // Defaults are 0.7, 0.0, 0.02. // // NAV_ROLL_INT_MAX OPTIONAL // // Maximum control offset due to the integral. This prevents the control // output from being overdriven due to a persistent offset (e.g. crosstracking). // Default is 5 degrees. // // NAV_PITCH_ASP_P OPTIONAL // NAV_PITCH_ASP_I OPTIONAL // NAV_PITCH_ASP_D OPTIONAL // // P, I and D terms for pitch adjustments made to maintain airspeed. // Defaults are 0.65, 0, 0. // // NAV_PITCH_ASP_INT_MAX OPTIONAL // // Maximum pitch offset due to the integral. This limits the control // output from being overdriven due to a persistent offset (eg. inability // to maintain the programmed airspeed). // Default is 5 degrees. // // NAV_PITCH_ALT_P OPTIONAL // NAV_PITCH_ALT_I OPTIONAL // NAV_PITCH_ALT_D OPTIONAL // // P, I and D terms for pitch adjustments made to maintain altitude. // Defaults are 0.65, 0, 0. // // NAV_PITCH_ALT_INT_MAX OPTIONAL // // Maximum pitch offset due to the integral. This limits the control // output from being overdriven due to a persistent offset (eg. inability // to maintain the programmed altitude). // Default is 5 meters. // #define NAV_ROLL_P 0.7 #define NAV_ROLL_I 0.001 #define NAV_ROLL_D 0.06 #define NAV_ROLL_INT_MAX 5 #define NAV_PITCH_ASP_P 0.0 #define NAV_PITCH_ASP_I 0.0 #define NAV_PITCH_ASP_D 0.0 #define NAV_PITCH_ASP_INT_MAX 5 #define NAV_PITCH_ALT_P 0.0 #define NAV_PITCH_ALT_I 0.0 #define NAV_PITCH_ALT_D 0.0 #define NAV_PITCH_ALT_INT_MAX 5 ////////////////////////////////////////////////////////////////////////////// // Energy/Altitude control gains // // The Energy/altitude control system uses throttle input to control aircraft // altitude. // // The P term is the primary tuning value. This determines how the throttle // setting varies in proportion to the required correction. // // The I term is used to compensate for small offsets. // // The D term is used to control overshoot. Avoid adjusting this term if // you are not familiar with tuning PID loops. // // Note units of this control loop are unusual. PID input is in m**2/s**2. // // THROTTLE_TE_P OPTIONAL // THROTTLE_TE_I OPTIONAL // THROTTLE_TE_D OPTIONAL // // P, I and D terms for throttle adjustments made to control altitude. // Defaults are 0.5, 0, 0. // // THROTTLE_TE_INT_MAX OPTIONAL // // Maximum throttle input due to the integral term. This limits the // throttle from being overdriven due to a persistent offset (e.g. // inability to maintain the programmed altitude). // Default is 20%. // // THROTTLE_SLEW_LIMIT OPTIONAL // // Limits the slew rate of the throttle, in percent per second. Helps // avoid sudden throttle changes, which can destabilise the aircraft. // A setting of zero disables the feature. // Default is zero (disabled). // // P_TO_T OPTIONAL // // Pitch to throttle feed-forward gain. Default is 0. // // T_TO_P OPTIONAL // // Throttle to pitch feed-forward gain. Default is 0. // #define THROTTLE_TE_P 0.1 #define THROTTLE_TE_I 0.0 #define THROTTLE_TE_D 0.0 #define THROTTLE_TE_INT_MAX 20 #define THROTTLE_SLEW_LIMIT 0 #define P_TO_T 0.0 #define T_TO_P 0 ////////////////////////////////////////////////////////////////////////////// // Crosstrack compensation // // XTRACK_GAIN OPTIONAL // // Crosstrack compensation in degrees per metre off track. // Default value is 1.0 degrees per metre. Values lower than 0.001 will // disable crosstrack compensation. // // XTRACK_ENTRY_ANGLE OPTIONAL // // Maximum angle used to correct for track following. // Default value is 30 degrees. // #define XTRACK_GAIN 1 // deg/m #define XTRACK_ENTRY_ANGLE 20 // deg ///////////////////////////////////////////////////////////////////////////// // Navigation defaults // // WP_RADIUS_DEFAULT OPTIONAL // // When the user performs a factory reset on the APM, set the waypoint radius // (the radius from a target waypoint within which the APM will consider // itself to have arrived at the waypoint) to this value in meters. This is // mainly intended to allow users to start using the APM without running the // WaypointWriter first. // // LOITER_RADIUS_DEFAULT OPTIONAL // // When the user performs a factory reset on the APM, set the loiter radius // (the distance the APM will attempt to maintain from a waypoint while // loitering) to this value in meters. This is mainly intended to allow // users to start using the APM without running the WaypointWriter first. // // USE_CURRENT_ALT OPTIONAL // ALT_HOLD_HOME OPTIONAL // // When the user performs a factory reset on the APM, set the flag for weather // the current altitude or ALT_HOLD_HOME altitude should be used for Return To Launch. // Also, set the value of USE_CURRENT_ALT in meters. This is mainly intended to allow // users to start using the APM without running the WaypointWriter first. // #define WP_RADIUS_DEFAULT 1 // meters #define LOITER_RADIUS_DEFAULT 5 // 60 #define USE_CURRENT_ALT TRUE #define ALT_HOLD_HOME 0 ////////////////////////////////////////////////////////////////////////////// // INPUT_VOLTAGE OPTIONAL // // In order to have accurate pressure and battery voltage readings, this // value should be set to the voltage measured on the 5V rail on the oilpan. // // See the manual for more details. The default value should be close. // #define INPUT_VOLTAGE 5.2 //