mirror of https://github.com/ArduPilot/ardupilot
349 lines
13 KiB
C++
349 lines
13 KiB
C++
#include <AP_HAL/AP_HAL.h>
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#include "AP_InertialSensor_SITL.h"
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#include <SITL/SITL.h>
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#include <stdio.h>
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#if CONFIG_HAL_BOARD == HAL_BOARD_SITL
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const extern AP_HAL::HAL& hal;
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AP_InertialSensor_SITL::AP_InertialSensor_SITL(AP_InertialSensor &imu, const uint16_t sample_rates[]) :
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AP_InertialSensor_Backend(imu),
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gyro_sample_hz(sample_rates[0]),
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accel_sample_hz(sample_rates[1])
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{
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}
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/*
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detect the sensor
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*/
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AP_InertialSensor_Backend *AP_InertialSensor_SITL::detect(AP_InertialSensor &_imu, const uint16_t sample_rates[])
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{
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AP_InertialSensor_SITL *sensor = new AP_InertialSensor_SITL(_imu, sample_rates);
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if (sensor == nullptr) {
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return nullptr;
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}
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if (!sensor->init_sensor()) {
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delete sensor;
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return nullptr;
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}
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return sensor;
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}
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bool AP_InertialSensor_SITL::init_sensor(void)
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{
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sitl = AP::sitl();
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if (sitl == nullptr) {
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return false;
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}
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return true;
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}
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// calculate a noisy noise component
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static float calculate_noise(float noise, float noise_variation) {
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return noise * (1.0f + noise_variation * rand_float());
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}
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float AP_InertialSensor_SITL::get_temperature(void)
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{
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if (!is_zero(sitl->imu_temp_fixed)) {
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// user wants fixed temperature
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return sitl->imu_temp_fixed;
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}
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uint32_t now = AP_HAL::millis();
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if (temp_start_ms == 0) {
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temp_start_ms = now;
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}
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// follow a curve with given start, end and time constant
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const float tsec = (AP_HAL::millis() - temp_start_ms) * 0.001f;
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const float T0 = sitl->imu_temp_start;
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const float T1 = sitl->imu_temp_end;
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const float tconst = sitl->imu_temp_tconst;
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return T1 - (T1 - T0) * expf(-tsec / tconst);
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}
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/*
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generate an accelerometer sample
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*/
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void AP_InertialSensor_SITL::generate_accel()
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{
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Vector3f accel_accum;
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uint8_t nsamples = enable_fast_sampling(accel_instance) ? 4 : 1;
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float T = get_temperature();
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for (uint8_t j = 0; j < nsamples; j++) {
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Vector3f accel = Vector3f(sitl->state.xAccel,
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sitl->state.yAccel,
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sitl->state.zAccel);
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const Vector3f &accel_trim = sitl->accel_trim.get();
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if (!accel_trim.is_zero()) {
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Matrix3f trim_rotation;
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trim_rotation.from_euler(accel_trim.x, accel_trim.y, 0);
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accel = trim_rotation.transposed() * accel;
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}
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// add scaling
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Vector3f accel_scale = sitl->accel_scale[accel_instance].get();
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// note that we divide so the SIM_ACC values match the
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// INS_ACCSCAL values
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if (!is_zero(accel_scale.x)) {
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accel.x /= accel_scale.x;
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}
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if (!is_zero(accel_scale.y)) {
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accel.y /= accel_scale.y;
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}
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if (!is_zero(accel_scale.z)) {
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accel.z /= accel_scale.z;
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}
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// apply bias
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const Vector3f &accel_bias = sitl->accel_bias[accel_instance].get();
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accel += accel_bias;
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// minimum noise levels are 2 bits, but averaged over many
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// samples, giving around 0.01 m/s/s
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float accel_noise = 0.01f;
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float noise_variation = 0.05f;
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// this smears the individual motor peaks somewhat emulating physical motors
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float freq_variation = 0.12f;
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// add in sensor noise
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accel += Vector3f{rand_float(), rand_float(), rand_float()} * accel_noise;
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bool motors_on = sitl->throttle > sitl->ins_noise_throttle_min;
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// on a real 180mm copter gyro noise varies between 0.8-4 m/s/s for throttle 0.2-0.8
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// giving a accel noise variation of 5.33 m/s/s over the full throttle range
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if (motors_on) {
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// add extra noise when the motors are on
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accel_noise = sitl->accel_noise[accel_instance];
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}
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// VIB_FREQ is a static vibration applied to each axis
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const Vector3f &vibe_freq = sitl->vibe_freq;
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if (!vibe_freq.is_zero() && motors_on) {
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accel.x += sinf(accel_time * 2 * M_PI * vibe_freq.x) * calculate_noise(accel_noise, noise_variation);
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accel.y += sinf(accel_time * 2 * M_PI * vibe_freq.y) * calculate_noise(accel_noise, noise_variation);
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accel.z += sinf(accel_time * 2 * M_PI * vibe_freq.z) * calculate_noise(accel_noise, noise_variation);
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accel_time += 1.0f / (accel_sample_hz * nsamples);
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}
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// VIB_MOT_MAX is a rpm-scaled vibration applied to each axis
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if (!is_zero(sitl->vibe_motor) && motors_on) {
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for (uint8_t i = 0; i < sitl->state.num_motors; i++) {
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float &phase = accel_motor_phase[i];
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float motor_freq = calculate_noise(sitl->state.rpm[sitl->state.vtol_motor_start+i] / 60.0f, freq_variation);
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float phase_incr = motor_freq * 2 * M_PI / (accel_sample_hz * nsamples);
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phase += phase_incr;
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if (phase_incr > M_PI) {
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phase -= 2 * M_PI;
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}
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else if (phase_incr < -M_PI) {
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phase += 2 * M_PI;
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}
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accel.x += sinf(phase) * calculate_noise(accel_noise * sitl->vibe_motor_scale, noise_variation);
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accel.y += sinf(phase) * calculate_noise(accel_noise * sitl->vibe_motor_scale, noise_variation);
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accel.z += sinf(phase) * calculate_noise(accel_noise * sitl->vibe_motor_scale, noise_variation);
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}
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}
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// correct for the acceleration due to the IMU position offset and angular acceleration
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// correct for the centripetal acceleration
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// only apply corrections to first accelerometer
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Vector3f pos_offset = sitl->imu_pos_offset;
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if (!pos_offset.is_zero()) {
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// calculate sensed acceleration due to lever arm effect
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// Note: the % operator has been overloaded to provide a cross product
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Vector3f angular_accel = Vector3f(radians(sitl->state.angAccel.x), radians(sitl->state.angAccel.y), radians(sitl->state.angAccel.z));
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Vector3f lever_arm_accel = angular_accel % pos_offset;
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// calculate sensed acceleration due to centripetal acceleration
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Vector3f angular_rate = Vector3f(radians(sitl->state.rollRate), radians(sitl->state.pitchRate), radians(sitl->state.yawRate));
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Vector3f centripetal_accel = angular_rate % (angular_rate % pos_offset);
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// apply corrections
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accel += lever_arm_accel + centripetal_accel;
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}
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if (fabsf(sitl->accel_fail[accel_instance]) > 1.0e-6f) {
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accel.x = accel.y = accel.z = sitl->accel_fail[accel_instance];
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}
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sitl->imu_tcal[gyro_instance].sitl_apply_accel(T, accel);
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_notify_new_accel_sensor_rate_sample(accel_instance, accel);
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accel_accum += accel;
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}
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accel_accum /= nsamples;
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_rotate_and_correct_accel(accel_instance, accel_accum);
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_notify_new_accel_raw_sample(accel_instance, accel_accum, AP_HAL::micros64());
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_publish_temperature(accel_instance, get_temperature());
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}
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/*
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generate a gyro sample
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*/
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void AP_InertialSensor_SITL::generate_gyro()
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{
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Vector3f gyro_accum;
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uint8_t nsamples = enable_fast_sampling(gyro_instance) ? 8 : 1;
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for (uint8_t j = 0; j < nsamples; j++) {
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float p = radians(sitl->state.rollRate) + gyro_drift();
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float q = radians(sitl->state.pitchRate) + gyro_drift();
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float r = radians(sitl->state.yawRate) + gyro_drift();
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// minimum gyro noise is less than 1 bit
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float gyro_noise = ToRad(0.04f);
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float noise_variation = 0.05f;
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// this smears the individual motor peaks somewhat emulating physical motors
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float freq_variation = 0.12f;
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// add in sensor noise
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p += gyro_noise * rand_float();
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q += gyro_noise * rand_float();
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r += gyro_noise * rand_float();
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bool motors_on = sitl->throttle > sitl->ins_noise_throttle_min;
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// on a real 180mm copter gyro noise varies between 0.2-0.4 rad/s for throttle 0.2-0.8
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// giving a gyro noise variation of 0.33 rad/s or 20deg/s over the full throttle range
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if (motors_on) {
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// add extra noise when the motors are on
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gyro_noise = ToRad(sitl->gyro_noise[gyro_instance]) * sitl->throttle;
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}
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// VIB_FREQ is a static vibration applied to each axis
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const Vector3f &vibe_freq = sitl->vibe_freq;
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if (vibe_freq.is_zero() && is_zero(sitl->vibe_motor)) {
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// no rpm noise, so add in background noise if any
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p += gyro_noise * rand_float();
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q += gyro_noise * rand_float();
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r += gyro_noise * rand_float();
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}
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if (!vibe_freq.is_zero() && motors_on) {
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p += sinf(gyro_time * 2 * M_PI * vibe_freq.x) * calculate_noise(gyro_noise, noise_variation);
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q += sinf(gyro_time * 2 * M_PI * vibe_freq.y) * calculate_noise(gyro_noise, noise_variation);
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r += sinf(gyro_time * 2 * M_PI * vibe_freq.z) * calculate_noise(gyro_noise, noise_variation);
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gyro_time += 1.0f / (gyro_sample_hz * nsamples);
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}
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// VIB_MOT_MAX is a rpm-scaled vibration applied to each axis
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if (!is_zero(sitl->vibe_motor) && motors_on) {
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for (uint8_t i = 0; i < sitl->state.num_motors; i++) {
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float motor_freq = calculate_noise(sitl->state.rpm[sitl->state.vtol_motor_start+i] / 60.0f, freq_variation);
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float phase_incr = motor_freq * 2 * M_PI / (gyro_sample_hz * nsamples);
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float &phase = gyro_motor_phase[i];
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phase += phase_incr;
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if (phase_incr > M_PI) {
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phase -= 2 * M_PI;
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}
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else if (phase_incr < -M_PI) {
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phase += 2 * M_PI;
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}
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p += sinf(phase) * calculate_noise(gyro_noise * sitl->vibe_motor_scale, noise_variation);
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q += sinf(phase) * calculate_noise(gyro_noise * sitl->vibe_motor_scale, noise_variation);
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r += sinf(phase) * calculate_noise(gyro_noise * sitl->vibe_motor_scale, noise_variation);
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}
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}
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Vector3f gyro = Vector3f(p, q, r);
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sitl->imu_tcal[gyro_instance].sitl_apply_gyro(get_temperature(), gyro);
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// add in gyro scaling
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Vector3f scale = sitl->gyro_scale[gyro_instance];
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gyro.x *= (1 + scale.x * 0.01f);
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gyro.y *= (1 + scale.y * 0.01f);
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gyro.z *= (1 + scale.z * 0.01f);
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gyro_accum += gyro;
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_notify_new_gyro_sensor_rate_sample(gyro_instance, gyro);
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}
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gyro_accum /= nsamples;
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_rotate_and_correct_gyro(gyro_instance, gyro_accum);
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_notify_new_gyro_raw_sample(gyro_instance, gyro_accum, AP_HAL::micros64());
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}
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void AP_InertialSensor_SITL::timer_update(void)
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{
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uint64_t now = AP_HAL::micros64();
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#if 0
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// insert a 1s pause in IMU data. This triggers a pause in EK2
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// processing that leads to some interesting issues
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if (now > 5e6 && now < 6e6) {
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return;
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}
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#endif
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if (sitl == nullptr) {
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return;
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}
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if (now >= next_accel_sample) {
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if (((1U << accel_instance) & sitl->accel_fail_mask) == 0) {
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generate_accel();
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if (next_accel_sample == 0) {
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next_accel_sample = now + 1000000UL / accel_sample_hz;
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} else {
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while (now >= next_accel_sample) {
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next_accel_sample += 1000000UL / accel_sample_hz;
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}
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}
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}
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}
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if (now >= next_gyro_sample) {
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if (((1U << gyro_instance) & sitl->gyro_fail_mask) == 0) {
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generate_gyro();
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if (next_gyro_sample == 0) {
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next_gyro_sample = now + 1000000UL / gyro_sample_hz;
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} else {
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while (now >= next_gyro_sample) {
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next_gyro_sample += 1000000UL / gyro_sample_hz;
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}
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}
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}
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}
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}
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float AP_InertialSensor_SITL::gyro_drift(void)
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{
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if (is_zero(sitl->drift_speed) ||
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is_zero(sitl->drift_time)) {
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return 0;
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}
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double period = sitl->drift_time * 2;
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double minutes = fmod(AP_HAL::micros64() / 60.0e6, period);
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if (minutes < period/2) {
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return minutes * ToRad(sitl->drift_speed);
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}
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return (period - minutes) * ToRad(sitl->drift_speed);
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}
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bool AP_InertialSensor_SITL::update(void)
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{
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update_accel(accel_instance);
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update_gyro(gyro_instance);
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return true;
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}
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uint8_t AP_InertialSensor_SITL::bus_id = 0;
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void AP_InertialSensor_SITL::start()
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{
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gyro_instance = _imu.register_gyro(gyro_sample_hz,
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AP_HAL::Device::make_bus_id(AP_HAL::Device::BUS_TYPE_SITL, bus_id, 1, DEVTYPE_SITL));
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accel_instance = _imu.register_accel(accel_sample_hz,
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AP_HAL::Device::make_bus_id(AP_HAL::Device::BUS_TYPE_SITL, bus_id, 2, DEVTYPE_SITL));
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bus_id++;
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hal.scheduler->register_timer_process(FUNCTOR_BIND_MEMBER(&AP_InertialSensor_SITL::timer_update, void));
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}
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#endif // HAL_BOARD_SITL
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