/**************************************************************************** * * Copyright (c) 2019-2020 PX4 Development Team. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in * the documentation and/or other materials provided with the * distribution. * 3. Neither the name PX4 nor the names of its contributors may be * used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE * COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS * OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN * ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE * POSSIBILITY OF SUCH DAMAGE. * ****************************************************************************/ /** * @file sih.cpp * Simulator in Hardware * * @author Romain Chiappinelli * * Coriolis g Corporation - January 2019 */ #include "sih.hpp" #include #include #include // to get PWM flags using namespace math; using namespace matrix; using namespace time_literals; Sih::Sih() : ModuleParams(nullptr), ScheduledWorkItem(MODULE_NAME, px4::wq_configurations::rate_ctrl) { _px4_accel.set_temperature(T1_C); _px4_gyro.set_temperature(T1_C); _px4_mag.set_temperature(T1_C); parameters_updated(); init_variables(); gps_no_fix(); const hrt_abstime task_start = hrt_absolute_time(); _last_run = task_start; _gps_time = task_start; _serial_time = task_start; _dist_snsr_time = task_start; } Sih::~Sih() { perf_free(_loop_perf); perf_free(_loop_interval_perf); } bool Sih::init() { int rate = _imu_gyro_ratemax.get(); // default to 250 Hz (4000 us interval) if (rate <= 0) { rate = 250; } // 200 - 2000 Hz int interval_us = math::constrain(int(roundf(1e6f / rate)), 500, 5000); ScheduleOnInterval(interval_us); return true; } void Sih::Run() { perf_count(_loop_interval_perf); // check for parameter updates if (_parameter_update_sub.updated()) { // clear update parameter_update_s pupdate; _parameter_update_sub.copy(&pupdate); // update parameters from storage updateParams(); parameters_updated(); } perf_begin(_loop_perf); _now = hrt_absolute_time(); _dt = (_now - _last_run) * 1e-6f; _last_run = _now; read_motors(); generate_force_and_torques(); equations_of_motion(); reconstruct_sensors_signals(); // update IMU every iteration _px4_accel.update(_now, _acc(0), _acc(1), _acc(2)); _px4_gyro.update(_now, _gyro(0), _gyro(1), _gyro(2)); // magnetometer published at 50 Hz if (_now - _mag_time >= 20_ms && fabs(_mag_offset_x) < 10000 && fabs(_mag_offset_y) < 10000 && fabs(_mag_offset_z) < 10000) { _mag_time = _now; _px4_mag.update(_now, _mag(0), _mag(1), _mag(2)); } // baro published at 20 Hz if (_now - _baro_time >= 50_ms && fabs(_baro_offset_m) < 10000) { _baro_time = _now; _px4_baro.set_temperature(_baro_temp_c); _px4_baro.update(_now, _baro_p_mBar); } // gps published at 20Hz if (_now - _gps_time >= 50_ms) { _gps_time = _now; send_gps(); } // distance sensor published at 50 Hz if (_now - _dist_snsr_time >= 20_ms) { _dist_snsr_time = _now; send_dist_snsr(); } // send uart message every 40 ms if (_now - _serial_time >= 40_ms) { _serial_time = _now; publish_sih(); // publish _sih message for debug purpose } perf_end(_loop_perf); } // store the parameters in a more convenient form void Sih::parameters_updated() { _T_MAX = _sih_t_max.get(); _Q_MAX = _sih_q_max.get(); _L_ROLL = _sih_l_roll.get(); _L_PITCH = _sih_l_pitch.get(); _KDV = _sih_kdv.get(); _KDW = _sih_kdw.get(); _H0 = _sih_h0.get(); _LAT0 = (double)_sih_lat0.get() * 1.0e-7; _LON0 = (double)_sih_lon0.get() * 1.0e-7; _COS_LAT0 = cosl((long double)radians(_LAT0)); _MASS = _sih_mass.get(); _W_I = Vector3f(0.0f, 0.0f, _MASS * CONSTANTS_ONE_G); _I = diag(Vector3f(_sih_ixx.get(), _sih_iyy.get(), _sih_izz.get())); _I(0, 1) = _I(1, 0) = _sih_ixy.get(); _I(0, 2) = _I(2, 0) = _sih_ixz.get(); _I(1, 2) = _I(2, 1) = _sih_iyz.get(); _Im1 = inv(_I); _mu_I = Vector3f(_sih_mu_x.get(), _sih_mu_y.get(), _sih_mu_z.get()); _gps_used = _sih_gps_used.get(); _baro_offset_m = _sih_baro_offset.get(); _mag_offset_x = _sih_mag_offset_x.get(); _mag_offset_y = _sih_mag_offset_y.get(); _mag_offset_z = _sih_mag_offset_z.get(); _distance_snsr_min = _sih_distance_snsr_min.get(); _distance_snsr_max = _sih_distance_snsr_max.get(); } // initialization of the variables for the simulator void Sih::init_variables() { srand(1234); // initialize the random seed once before calling generate_wgn() _p_I = Vector3f(0.0f, 0.0f, 0.0f); _v_I = Vector3f(0.0f, 0.0f, 0.0f); _q = Quatf(1.0f, 0.0f, 0.0f, 0.0f); _w_B = Vector3f(0.0f, 0.0f, 0.0f); _u[0] = _u[1] = _u[2] = _u[3] = 0.0f; } void Sih::gps_fix() { _sensor_gps.fix_type = 3; // 3D fix _sensor_gps.satellites_used = _gps_used; _sensor_gps.heading = NAN; _sensor_gps.heading_offset = NAN; _sensor_gps.s_variance_m_s = 0.5f; _sensor_gps.c_variance_rad = 0.1f; _sensor_gps.eph = 0.9f; _sensor_gps.epv = 1.78f; _sensor_gps.hdop = 0.7f; _sensor_gps.vdop = 1.1f; } void Sih::gps_no_fix() { _sensor_gps.fix_type = 0; // 3D fix _sensor_gps.satellites_used = _gps_used; _sensor_gps.heading = NAN; _sensor_gps.heading_offset = NAN; _sensor_gps.s_variance_m_s = 100.f; _sensor_gps.c_variance_rad = 100.f; _sensor_gps.eph = 100.f; _sensor_gps.epv = 100.f; _sensor_gps.hdop = 100.f; _sensor_gps.vdop = 100.f; } // read the motor signals outputted from the mixer void Sih::read_motors() { actuator_outputs_s actuators_out; if (_actuator_out_sub.update(&actuators_out)) { for (int i = 0; i < NB_MOTORS; i++) { // saturate the motor signals _u[i] = constrain((actuators_out.output[i] - PWM_DEFAULT_MIN) / (PWM_DEFAULT_MAX - PWM_DEFAULT_MIN), 0.0f, 1.0f); } } } // generate the motors thrust and torque in the body frame void Sih::generate_force_and_torques() { _T_B = Vector3f(0.0f, 0.0f, -_T_MAX * (+_u[0] + _u[1] + _u[2] + _u[3])); _Mt_B = Vector3f(_L_ROLL * _T_MAX * (-_u[0] + _u[1] + _u[2] - _u[3]), _L_PITCH * _T_MAX * (+_u[0] - _u[1] + _u[2] - _u[3]), _Q_MAX * (+_u[0] + _u[1] - _u[2] - _u[3])); _Fa_I = -_KDV * _v_I; // first order drag to slow down the aircraft _Ma_B = -_KDW * _w_B; // first order angular damper } // apply the equations of motion of a rigid body and integrate one step void Sih::equations_of_motion() { _C_IB = matrix::Dcm(_q); // body to inertial transformation // Equations of motion of a rigid body _p_I_dot = _v_I; // position differential _v_I_dot = (_W_I + _Fa_I + _C_IB * _T_B) / _MASS; // conservation of linear momentum _q_dot = _q.derivative1(_w_B); // attitude differential _w_B_dot = _Im1 * (_Mt_B + _Ma_B - _w_B.cross(_I * _w_B)); // conservation of angular momentum // fake ground, avoid free fall if (_p_I(2) > 0.0f && (_v_I_dot(2) > 0.0f || _v_I(2) > 0.0f)) { if (!_grounded) { // if we just hit the floor // for the accelerometer, compute the acceleration that will stop the vehicle in one time step _v_I_dot = -_v_I / _dt; } else { _v_I_dot.setZero(); } _v_I.setZero(); _w_B.setZero(); _grounded = true; } else { // integration: Euler forward _p_I = _p_I + _p_I_dot * _dt; _v_I = _v_I + _v_I_dot * _dt; _q = _q + _q_dot * _dt; // as given in attitude_estimator_q_main.cpp _q.normalize(); _w_B = _w_B + _w_B_dot * _dt; _grounded = false; } } // reconstruct the noisy sensor signals void Sih::reconstruct_sensors_signals() { // The sensor signals reconstruction and noise levels are from // Bulka, Eitan, and Meyer Nahon. "Autonomous fixed-wing aerobatics: from theory to flight." // In 2018 IEEE International Conference on Robotics and Automation (ICRA), pp. 6573-6580. IEEE, 2018. // IMU _acc = _C_IB.transpose() * (_v_I_dot - Vector3f(0.0f, 0.0f, CONSTANTS_ONE_G)) + noiseGauss3f(0.5f, 1.7f, 1.4f); _gyro = _w_B + noiseGauss3f(0.14f, 0.07f, 0.03f); _mag = _C_IB.transpose() * _mu_I + noiseGauss3f(0.02f, 0.02f, 0.03f); _mag(0) += _mag_offset_x; _mag(1) += _mag_offset_y; _mag(2) += _mag_offset_z; // barometer float altitude = (_H0 - _p_I(2)) + _baro_offset_m + generate_wgn() * 0.14f; // altitude with noise _baro_p_mBar = CONSTANTS_STD_PRESSURE_MBAR * // reconstructed pressure in mBar powf((1.0f + altitude * TEMP_GRADIENT / T1_K), -CONSTANTS_ONE_G / (TEMP_GRADIENT * CONSTANTS_AIR_GAS_CONST)); _baro_temp_c = T1_K + CONSTANTS_ABSOLUTE_NULL_CELSIUS + TEMP_GRADIENT * altitude; // reconstructed temperture in celcius // GPS _gps_lat_noiseless = _LAT0 + degrees((double)_p_I(0) / CONSTANTS_RADIUS_OF_EARTH); _gps_lon_noiseless = _LON0 + degrees((double)_p_I(1) / CONSTANTS_RADIUS_OF_EARTH) / _COS_LAT0; _gps_alt_noiseless = _H0 - _p_I(2); _gps_lat = _gps_lat_noiseless + (double)(generate_wgn() * 7.2e-6f); // latitude in degrees _gps_lon = _gps_lon_noiseless + (double)(generate_wgn() * 1.75e-5f); // longitude in degrees _gps_alt = _gps_alt_noiseless + generate_wgn() * 1.78f; _gps_vel = _v_I + noiseGauss3f(0.06f, 0.077f, 0.158f); } void Sih::send_gps() { _sensor_gps.timestamp = _now; _sensor_gps.lat = (int32_t)(_gps_lat * 1e7); // Latitude in 1E-7 degrees _sensor_gps.lon = (int32_t)(_gps_lon * 1e7); // Longitude in 1E-7 degrees _sensor_gps.alt = (int32_t)(_gps_alt * 1000.0f); // Altitude in 1E-3 meters above MSL, (millimetres) _sensor_gps.alt_ellipsoid = (int32_t)(_gps_alt * 1000); // Altitude in 1E-3 meters bove Ellipsoid, (millimetres) _sensor_gps.vel_ned_valid = true; // True if NED velocity is valid _sensor_gps.vel_m_s = sqrtf(_gps_vel(0) * _gps_vel(0) + _gps_vel(1) * _gps_vel( 1)); // GPS ground speed, (metres/sec) _sensor_gps.vel_n_m_s = _gps_vel(0); // GPS North velocity, (metres/sec) _sensor_gps.vel_e_m_s = _gps_vel(1); // GPS East velocity, (metres/sec) _sensor_gps.vel_d_m_s = _gps_vel(2); // GPS Down velocity, (metres/sec) _sensor_gps.cog_rad = atan2(_gps_vel(1), _gps_vel(0)); // Course over ground (NOT heading, but direction of movement), -PI..PI, (radians) if (_gps_used >= 4) { gps_fix(); } else { gps_no_fix(); } _sensor_gps_pub.publish(_sensor_gps); } void Sih::send_dist_snsr() { _distance_snsr.timestamp = _now; _distance_snsr.type = distance_sensor_s::MAV_DISTANCE_SENSOR_LASER; _distance_snsr.orientation = distance_sensor_s::ROTATION_DOWNWARD_FACING; _distance_snsr.min_distance = _distance_snsr_min; _distance_snsr.max_distance = _distance_snsr_max; _distance_snsr.signal_quality = -1; _distance_snsr.device_id = 0; _distance_snsr.current_distance = -_p_I(2) / _C_IB(2, 2); if (_distance_snsr.current_distance > _distance_snsr_max) { // this is based on lightware lw20 behavior _distance_snsr.current_distance = UINT16_MAX / 100.f; } _distance_snsr_pub.publish(_distance_snsr); } void Sih::publish_sih() { // publish angular velocity groundtruth _vehicle_angular_velocity_gt.timestamp = hrt_absolute_time(); _vehicle_angular_velocity_gt.xyz[0] = _w_B(0); // rollspeed; _vehicle_angular_velocity_gt.xyz[1] = _w_B(1); // pitchspeed; _vehicle_angular_velocity_gt.xyz[2] = _w_B(2); // yawspeed; _vehicle_angular_velocity_gt_pub.publish(_vehicle_angular_velocity_gt); // publish attitude groundtruth _att_gt.timestamp = hrt_absolute_time(); _att_gt.q[0] = _q(0); _att_gt.q[1] = _q(1); _att_gt.q[2] = _q(2); _att_gt.q[3] = _q(3); _att_gt_pub.publish(_att_gt); _gpos_gt.timestamp = hrt_absolute_time(); _gpos_gt.lat = _gps_lat_noiseless; _gpos_gt.lon = _gps_lon_noiseless; _gpos_gt.alt = _gps_alt_noiseless; _gpos_gt_pub.publish(_gpos_gt); } float Sih::generate_wgn() // generate white Gaussian noise sample with std=1 { // algorithm 1: // float temp=((float)(rand()+1))/(((float)RAND_MAX+1.0f)); // return sqrtf(-2.0f*logf(temp))*cosf(2.0f*M_PI_F*rand()/RAND_MAX); // algorithm 2: from BlockRandGauss.hpp static float V1, V2, S; static bool phase = true; float X; if (phase) { do { float U1 = (float)rand() / RAND_MAX; float U2 = (float)rand() / RAND_MAX; V1 = 2.0f * U1 - 1.0f; V2 = 2.0f * U2 - 1.0f; S = V1 * V1 + V2 * V2; } while (S >= 1.0f || fabsf(S) < 1e-8f); X = V1 * float(sqrtf(-2.0f * float(logf(S)) / S)); } else { X = V2 * float(sqrtf(-2.0f * float(logf(S)) / S)); } phase = !phase; return X; } // generate white Gaussian noise sample vector with specified std Vector3f Sih::noiseGauss3f(float stdx, float stdy, float stdz) { return Vector3f(generate_wgn() * stdx, generate_wgn() * stdy, generate_wgn() * stdz); } int Sih::task_spawn(int argc, char *argv[]) { Sih *instance = new Sih(); if (instance) { _object.store(instance); _task_id = task_id_is_work_queue; if (instance->init()) { return PX4_OK; } } else { PX4_ERR("alloc failed"); } delete instance; _object.store(nullptr); _task_id = -1; return PX4_ERROR; } int Sih::custom_command(int argc, char *argv[]) { return print_usage("unknown command"); } int Sih::print_usage(const char *reason) { if (reason) { PX4_WARN("%s\n", reason); } PRINT_MODULE_DESCRIPTION( R"DESCR_STR( ### Description This module provide a simulator for quadrotors running fully inside the hardware autopilot. This simulator subscribes to "actuator_outputs" which are the actuator pwm signals given by the mixer. This simulator publishes the sensors signals corrupted with realistic noise in order to incorporate the state estimator in the loop. ### Implementation The simulator implements the equations of motion using matrix algebra. Quaternion representation is used for the attitude. Forward Euler is used for integration. Most of the variables are declared global in the .hpp file to avoid stack overflow. )DESCR_STR"); PRINT_MODULE_USAGE_NAME("sih", "simulation"); PRINT_MODULE_USAGE_COMMAND("start"); PRINT_MODULE_USAGE_DEFAULT_COMMANDS(); return 0; } extern "C" __EXPORT int sih_main(int argc, char *argv[]) { return Sih::main(argc, argv); }