mirror of https://github.com/ArduPilot/ardupilot
313 lines
12 KiB
C++
313 lines
12 KiB
C++
/*
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This program is free software: you can redistribute it and/or modify
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it under the terms of the GNU General Public License as published by
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the Free Software Foundation, either version 3 of the License, or
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(at your option) any later version.
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This program is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with this program. If not, see <http://www.gnu.org/licenses/>.
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*/
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/*
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SITL.cpp - software in the loop state
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*/
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#include "SITL.h"
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#include <AP_Common/AP_Common.h>
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#include <AP_HAL/AP_HAL.h>
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#include <GCS_MAVLink/GCS_MAVLink.h>
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#include <AP_Logger/AP_Logger.h>
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extern const AP_HAL::HAL& hal;
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namespace SITL {
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SITL *SITL::_singleton = nullptr;
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// table of user settable parameters
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const AP_Param::GroupInfo SITL::var_info[] = {
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AP_GROUPINFO("BARO_RND", 0, SITL, baro_noise, 0.2f),
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AP_GROUPINFO("GYR_RND", 1, SITL, gyro_noise, 0),
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AP_GROUPINFO("ACC_RND", 2, SITL, accel_noise, 0),
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AP_GROUPINFO("MAG_RND", 3, SITL, mag_noise, 0),
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AP_GROUPINFO("GPS_DISABLE",4, SITL, gps_disable, 0),
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AP_GROUPINFO("DRIFT_SPEED",5, SITL, drift_speed, 0.05f),
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AP_GROUPINFO("DRIFT_TIME", 6, SITL, drift_time, 5),
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AP_GROUPINFO("GPS_DELAY", 7, SITL, gps_delay, 1),
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AP_GROUPINFO("ENGINE_MUL", 8, SITL, engine_mul, 1),
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AP_GROUPINFO("WIND_SPD", 9, SITL, wind_speed, 0),
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AP_GROUPINFO("WIND_DIR", 10, SITL, wind_direction, 180),
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AP_GROUPINFO("WIND_TURB", 11, SITL, wind_turbulance, 0),
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AP_GROUPINFO("GPS_TYPE", 12, SITL, gps_type, SITL::GPS_TYPE_UBLOX),
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AP_GROUPINFO("GPS_BYTELOSS", 13, SITL, gps_byteloss, 0),
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AP_GROUPINFO("GPS_NUMSATS", 14, SITL, gps_numsats, 10),
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AP_GROUPINFO("MAG_ERROR", 15, SITL, mag_error, 0),
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AP_GROUPINFO("SERVO_SPEED", 16, SITL, servo_speed, 0.14),
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AP_GROUPINFO("GPS_GLITCH", 17, SITL, gps_glitch, 0),
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AP_GROUPINFO("GPS_HZ", 18, SITL, gps_hertz, 5),
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AP_GROUPINFO("BATT_VOLTAGE", 19, SITL, batt_voltage, 12.6f),
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AP_GROUPINFO("ARSPD_RND", 20, SITL, arspd_noise, 0.5f),
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AP_GROUPINFO("ACCEL_FAIL", 21, SITL, accel_fail, 0),
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AP_GROUPINFO("BARO_DRIFT", 22, SITL, baro_drift, 0),
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AP_GROUPINFO("SONAR_GLITCH", 23, SITL, sonar_glitch, 0),
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AP_GROUPINFO("SONAR_RND", 24, SITL, sonar_noise, 0),
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AP_GROUPINFO("RC_FAIL", 25, SITL, rc_fail, 0),
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AP_GROUPINFO("GPS2_ENABLE", 26, SITL, gps2_enable, 0),
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AP_GROUPINFO("BARO_DISABLE", 27, SITL, baro_disable, 0),
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AP_GROUPINFO("FLOAT_EXCEPT", 28, SITL, float_exception, 1),
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AP_GROUPINFO("MAG_MOT", 29, SITL, mag_mot, 0),
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AP_GROUPINFO("ACC_BIAS", 30, SITL, accel_bias, 0),
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AP_GROUPINFO("BARO_GLITCH", 31, SITL, baro_glitch, 0),
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AP_GROUPINFO("SONAR_SCALE", 32, SITL, sonar_scale, 12.1212f),
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AP_GROUPINFO("FLOW_ENABLE", 33, SITL, flow_enable, 0),
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AP_GROUPINFO("TERRAIN", 34, SITL, terrain_enable, 1),
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AP_GROUPINFO("FLOW_RATE", 35, SITL, flow_rate, 10),
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AP_GROUPINFO("FLOW_DELAY", 36, SITL, flow_delay, 0),
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AP_GROUPINFO("GPS_DRIFTALT", 37, SITL, gps_drift_alt, 0),
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AP_GROUPINFO("BARO_DELAY", 38, SITL, baro_delay, 0),
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AP_GROUPINFO("MAG_DELAY", 39, SITL, mag_delay, 0),
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AP_GROUPINFO("WIND_DELAY", 40, SITL, wind_delay, 0),
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AP_GROUPINFO("MAG_OFS", 41, SITL, mag_ofs, 0),
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AP_GROUPINFO("ACC2_RND", 42, SITL, accel2_noise, 0),
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AP_GROUPINFO("ARSPD_FAIL", 43, SITL, arspd_fail, 0),
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AP_GROUPINFO("GYR_SCALE", 44, SITL, gyro_scale, 0),
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AP_GROUPINFO("ADSB_COUNT", 45, SITL, adsb_plane_count, -1),
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AP_GROUPINFO("ADSB_RADIUS", 46, SITL, adsb_radius_m, 10000),
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AP_GROUPINFO("ADSB_ALT", 47, SITL, adsb_altitude_m, 1000),
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AP_GROUPINFO("MAG_ALY", 48, SITL, mag_anomaly_ned, 0),
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AP_GROUPINFO("MAG_ALY_HGT", 49, SITL, mag_anomaly_hgt, 1.0f),
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AP_GROUPINFO("PIN_MASK", 50, SITL, pin_mask, 0),
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AP_GROUPINFO("ADSB_TX", 51, SITL, adsb_tx, 0),
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AP_GROUPINFO("SPEEDUP", 52, SITL, speedup, -1),
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AP_GROUPINFO("IMU_POS", 53, SITL, imu_pos_offset, 0),
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AP_GROUPINFO("GPS_POS", 54, SITL, gps_pos_offset, 0),
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AP_GROUPINFO("SONAR_POS", 55, SITL, rngfnd_pos_offset, 0),
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AP_GROUPINFO("FLOW_POS", 56, SITL, optflow_pos_offset, 0),
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AP_GROUPINFO("ACC2_BIAS", 57, SITL, accel2_bias, 0),
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AP_GROUPINFO("GPS_NOISE", 58, SITL, gps_noise, 0),
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AP_GROUPINFO("GP2_GLITCH", 59, SITL, gps2_glitch, 0),
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AP_GROUPINFO("ENGINE_FAIL", 60, SITL, engine_fail, 0),
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AP_GROUPINFO("GPS2_TYPE", 61, SITL, gps2_type, SITL::GPS_TYPE_UBLOX),
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AP_GROUPINFO("ODOM_ENABLE", 62, SITL, odom_enable, 0),
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AP_SUBGROUPEXTENSION("", 63, SITL, var_info2),
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AP_GROUPEND
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};
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// second table of user settable parameters for SITL.
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const AP_Param::GroupInfo SITL::var_info2[] = {
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AP_GROUPINFO("TEMP_START", 1, SITL, temp_start, 25),
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AP_GROUPINFO("TEMP_FLIGHT", 2, SITL, temp_flight, 35),
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AP_GROUPINFO("TEMP_TCONST", 3, SITL, temp_tconst, 30),
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AP_GROUPINFO("TEMP_BFACTOR", 4, SITL, temp_baro_factor, 0),
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AP_GROUPINFO("GPS_LOCKTIME", 5, SITL, gps_lock_time, 0),
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AP_GROUPINFO("ARSPD_FAIL_P", 6, SITL, arspd_fail_pressure, 0),
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AP_GROUPINFO("ARSPD_PITOT", 7, SITL, arspd_fail_pitot_pressure, 0),
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AP_GROUPINFO("GPS_ALT_OFS", 8, SITL, gps_alt_offset, 0),
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AP_GROUPINFO("ARSPD_SIGN", 9, SITL, arspd_signflip, 0),
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AP_GROUPINFO("WIND_DIR_Z", 10, SITL, wind_dir_z, 0),
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AP_GROUPINFO("ARSPD2_FAIL", 11, SITL, arspd2_fail, 0),
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AP_GROUPINFO("ARSPD2_FAILP",12, SITL, arspd2_fail_pressure, 0),
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AP_GROUPINFO("ARSPD2_PITOT",13, SITL, arspd2_fail_pitot_pressure, 0),
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AP_GROUPINFO("VICON_HSTLEN",14, SITL, vicon_observation_history_length, 0),
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AP_GROUPINFO("WIND_T" ,15, SITL, wind_type, SITL::WIND_TYPE_SQRT),
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AP_GROUPINFO("WIND_T_ALT" ,16, SITL, wind_type_alt, 60),
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AP_GROUPINFO("WIND_T_COEF", 17, SITL, wind_type_coef, 0.01f),
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AP_GROUPINFO("MAG_DIA", 18, SITL, mag_diag, 0),
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AP_GROUPINFO("MAG_ODI", 19, SITL, mag_offdiag, 0),
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AP_GROUPINFO("MAG_ORIENT", 20, SITL, mag_orient, 0),
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AP_GROUPINFO("RC_CHANCOUNT",21, SITL, rc_chancount, 16),
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// @Group: SPR_
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// @Path: ./SIM_Sprayer.cpp
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AP_SUBGROUPINFO(sprayer_sim, "SPR_", 22, SITL, Sprayer),
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// @Group: GRPS_
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// @Path: ./SIM_Gripper_Servo.cpp
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AP_SUBGROUPINFO(gripper_sim, "GRPS_", 23, SITL, Gripper_Servo),
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// @Group: GRPE_
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// @Path: ./SIM_Gripper_EPM.cpp
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AP_SUBGROUPINFO(gripper_epm_sim, "GRPE_", 24, SITL, Gripper_EPM),
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// weight on wheels pin
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AP_GROUPINFO("WOW_PIN", 25, SITL, wow_pin, -1),
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// vibration frequencies on each axis
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AP_GROUPINFO("VIB_FREQ", 26, SITL, vibe_freq, 0),
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// @Path: ./SIM_Parachute.cpp
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AP_SUBGROUPINFO(parachute_sim, "PARA_", 27, SITL, Parachute),
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// enable bandwidth limitting on telemetry ports:
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AP_GROUPINFO("BAUDLIMIT_EN", 28, SITL, telem_baudlimit_enable, 0),
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// @Group: PLD_
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// @Path: ./SIM_Precland.cpp
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AP_SUBGROUPINFO(precland_sim, "PLD_", 29, SITL, SIM_Precland),
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// apply a force to the vehicle over a period of time:
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AP_GROUPINFO("SHOVE_X", 30, SITL, shove.x, 0),
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AP_GROUPINFO("SHOVE_Y", 31, SITL, shove.y, 0),
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AP_GROUPINFO("SHOVE_Z", 32, SITL, shove.z, 0),
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AP_GROUPINFO("SHOVE_TIME", 33, SITL, shove.t, 0),
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// optical flow sensor measurement noise in rad/sec
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AP_GROUPINFO("FLOW_RND", 34, SITL, flow_noise, 0.05f),
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// accel and gyro fail masks
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AP_GROUPINFO("GYR_FAIL_MSK", 35, SITL, gyro_fail_mask, 0),
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AP_GROUPINFO("ACC_FAIL_MSK", 36, SITL, accel_fail_mask, 0),
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AP_GROUPINFO("TWIST_X", 37, SITL, twist.x, 0),
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AP_GROUPINFO("TWIST_Y", 38, SITL, twist.y, 0),
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AP_GROUPINFO("TWIST_Z", 39, SITL, twist.z, 0),
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AP_GROUPINFO("TWIST_TIME", 40, SITL, twist.t, 0),
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AP_GROUPINFO("GND_BEHAV", 41, SITL, gnd_behav, -1),
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AP_GROUPINFO("BARO_COUNT", 42, SITL, baro_count, 1),
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AP_GROUPINFO("GPS_HDG", 43, SITL, gps_hdg_enabled, 0),
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// sailboat wave and tide simulation parameters
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AP_GROUPINFO("WAVE_ENABLE", 44, SITL, wave.enable, 0.0f),
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AP_GROUPINFO("WAVE_LENGTH", 45, SITL, wave.length, 10.0f),
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AP_GROUPINFO("WAVE_AMP", 46, SITL, wave.amp, 0.5f),
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AP_GROUPINFO("WAVE_DIR", 47, SITL, wave.direction, 0.0f),
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AP_GROUPINFO("WAVE_SPEED", 48, SITL, wave.speed, 0.5f),
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AP_GROUPINFO("TIDE_DIR", 49, SITL, tide.direction, 0.0f),
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AP_GROUPINFO("TIDE_SPEED", 50, SITL, tide.speed, 0.0f),
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// the following coordinates are for CMAC, in Canberra
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AP_GROUPINFO("OPOS_LAT", 51, SITL, opos.lat, -35.363261f),
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AP_GROUPINFO("OPOS_LNG", 52, SITL, opos.lng, 149.165230f),
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AP_GROUPINFO("OPOS_ALT", 53, SITL, opos.alt, 584.0f),
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AP_GROUPINFO("OPOS_HDG", 54, SITL, opos.hdg, 353.0f),
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// extra delay per main loop
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AP_GROUPINFO("LOOP_DELAY", 55, SITL, loop_delay, 0),
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// @Path: ./SIM_Buzzer.cpp
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AP_SUBGROUPINFO(buzzer_sim, "BZ_", 56, SITL, Buzzer),
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// @Path: ./SIM_ToneAlarm.cpp
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AP_SUBGROUPINFO(tonealarm_sim, "TA_", 57, SITL, ToneAlarm),
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AP_GROUPEND
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};
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/* report SITL state via MAVLink */
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void SITL::simstate_send(mavlink_channel_t chan)
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{
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float yaw;
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// convert to same conventions as DCM
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yaw = state.yawDeg;
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if (yaw > 180) {
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yaw -= 360;
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}
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mavlink_msg_simstate_send(chan,
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ToRad(state.rollDeg),
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ToRad(state.pitchDeg),
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ToRad(yaw),
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state.xAccel,
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state.yAccel,
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state.zAccel,
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radians(state.rollRate),
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radians(state.pitchRate),
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radians(state.yawRate),
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state.latitude*1.0e7,
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state.longitude*1.0e7);
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}
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/* report SITL state to AP_Logger */
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void SITL::Log_Write_SIMSTATE()
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{
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float yaw;
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// convert to same conventions as DCM
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yaw = state.yawDeg;
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if (yaw > 180) {
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yaw -= 360;
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}
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struct log_AHRS pkt = {
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LOG_PACKET_HEADER_INIT(LOG_SIMSTATE_MSG),
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time_us : AP_HAL::micros64(),
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roll : (int16_t)(state.rollDeg*100),
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pitch : (int16_t)(state.pitchDeg*100),
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yaw : (uint16_t)(wrap_360_cd(yaw*100)),
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alt : (float)state.altitude,
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lat : (int32_t)(state.latitude*1.0e7),
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lng : (int32_t)(state.longitude*1.0e7),
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q1 : state.quaternion.q1,
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q2 : state.quaternion.q2,
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q3 : state.quaternion.q3,
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q4 : state.quaternion.q4,
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};
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AP::logger().WriteBlock(&pkt, sizeof(pkt));
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}
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/*
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convert a set of roll rates from earth frame to body frame
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output values are in radians/second
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*/
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void SITL::convert_body_frame(double rollDeg, double pitchDeg,
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double rollRate, double pitchRate, double yawRate,
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double *p, double *q, double *r)
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{
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double phi, theta, phiDot, thetaDot, psiDot;
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phi = ToRad(rollDeg);
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theta = ToRad(pitchDeg);
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phiDot = ToRad(rollRate);
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thetaDot = ToRad(pitchRate);
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psiDot = ToRad(yawRate);
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*p = phiDot - psiDot*sin(theta);
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*q = cos(phi)*thetaDot + sin(phi)*psiDot*cos(theta);
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*r = cos(phi)*psiDot*cos(theta) - sin(phi)*thetaDot;
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}
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/*
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convert angular velocities from body frame to
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earth frame.
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all inputs and outputs are in radians/s
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*/
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Vector3f SITL::convert_earth_frame(const Matrix3f &dcm, const Vector3f &gyro)
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{
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float p = gyro.x;
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float q = gyro.y;
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float r = gyro.z;
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float phi, theta, psi;
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dcm.to_euler(&phi, &theta, &psi);
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float phiDot = p + tanf(theta)*(q*sinf(phi) + r*cosf(phi));
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float thetaDot = q*cosf(phi) - r*sinf(phi);
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if (fabsf(cosf(theta)) < 1.0e-20f) {
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theta += 1.0e-10f;
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}
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float psiDot = (q*sinf(phi) + r*cosf(phi))/cosf(theta);
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return Vector3f(phiDot, thetaDot, psiDot);
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}
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} // namespace SITL
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namespace AP {
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SITL::SITL *sitl()
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{
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return SITL::SITL::get_singleton();
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}
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};
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