/* This program is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see . */ #include "AP_OpticalFlow_config.h" #if AP_OPTICALFLOW_CALIBRATOR_ENABLED #include "AP_OpticalFlow_Calibrator.h" #include #include const uint32_t AP_OPTICALFLOW_CAL_TIMEOUT_SEC = 120; // calibration timesout after 120 seconds const uint32_t AP_OPTICALFLOW_CAL_STATUSINTERVAL_SEC = 3; // status updates printed at 3 second intervals const float AP_OPTICALFLOW_CAL_YAW_MAX_RADS = radians(20); // maximum yaw rotation (must be low to ensure good scaling) const float AP_OPTICALFLOW_CAL_ROLLPITCH_MIN_RADS = radians(20); // minimum acceptable roll or pitch rotation const float AP_OPTICALFLOW_CAL_SCALE_MIN = 0.20f; // min acceptable scaling value. If resulting scaling is below this then the calibration fails const float AP_OPTICALFLOW_CAL_SCALE_MAX = 4.0f; // max acceptable scaling value. If resulting scaling is above this then the calibration fails const float AP_OPTICALFLOW_CAL_FITNESS_THRESH = 0.5f; // min acceptable fitness const float AP_OPTICALFLOW_CAL_RMS_FAILED = 1.0e30f; // calc_mean_squared_residuals returns this value when it fails to calculate a good value extern const AP_HAL::HAL& hal; // start the calibration void AP_OpticalFlow_Calibrator::start() { // exit immediately if already running if (_cal_state == CalState::RUNNING) { return; } _cal_state = CalState::RUNNING; _start_time_ms = AP_HAL::millis(); // clear samples buffers _cal_data[0].num_samples = 0; _cal_data[1].num_samples = 0; GCS_SEND_TEXT(MAV_SEVERITY_INFO, "FlowCal: Started"); } void AP_OpticalFlow_Calibrator::stop() { // exit immediately if already stopped if (_cal_state == CalState::NOT_STARTED) { return; } _cal_state = CalState::NOT_STARTED; GCS_SEND_TEXT(MAV_SEVERITY_INFO, "FlowCal: Stopped"); } // update the state machine and calculate scaling bool AP_OpticalFlow_Calibrator::update() { // prefix for reporting const char* prefix_str = "FlowCal:"; // while running add samples if (_cal_state == CalState::RUNNING) { uint32_t now_ms = AP_HAL::millis(); uint32_t timestamp_ms; Vector2f flow_rate, body_rate, los_pred; if (AP::ahrs().getOptFlowSample(timestamp_ms, flow_rate, body_rate, los_pred)) { add_sample(timestamp_ms, flow_rate, body_rate, los_pred); // while collecting samples display percentage complete if (now_ms - _last_report_ms > AP_OPTICALFLOW_CAL_STATUSINTERVAL_SEC * 1000UL) { _last_report_ms = now_ms; GCS_SEND_TEXT(MAV_SEVERITY_INFO, "%s x:%d%% y:%d%%", prefix_str, (int)((_cal_data[0].num_samples * 100.0 / AP_OPTICALFLOW_CAL_MAX_SAMPLES)), (int)((_cal_data[1].num_samples * 100.0 / AP_OPTICALFLOW_CAL_MAX_SAMPLES))); } // advance state once sample buffers are full if (sample_buffers_full()) { _cal_state = CalState::READY_TO_CALIBRATE; GCS_SEND_TEXT(MAV_SEVERITY_INFO, "%s samples collected", prefix_str); } } // check for timeout if (now_ms - _start_time_ms > AP_OPTICALFLOW_CAL_TIMEOUT_SEC * 1000UL) { GCS_SEND_TEXT(MAV_SEVERITY_INFO, "%s timeout", prefix_str); _cal_state = CalState::FAILED; } } // start calibration if (_cal_state == CalState::READY_TO_CALIBRATE) { // run calibration and mark failure or success if (run_calibration()) { _cal_state = CalState::SUCCESS; return true; } else { _cal_state = CalState::FAILED; } } // return indicating calibration is not complete return false; } // get final scaling values // scaling values used during sample collection should be multiplied by these scalars Vector2f AP_OpticalFlow_Calibrator::get_scalars() { // return best scaling values return Vector2f{_cal_data[0].best_scalar, _cal_data[1].best_scalar}; } // add new sample to the calibrator void AP_OpticalFlow_Calibrator::add_sample(uint32_t timestamp_ms, const Vector2f& flow_rate, const Vector2f& body_rate, const Vector2f& los_pred) { // return immediately if not running if (_cal_state != CalState::RUNNING) { return; } // check for duplicates if (timestamp_ms == _last_sample_timestamp_ms) { return; } _last_sample_timestamp_ms = timestamp_ms; // check yaw rotation is low const Vector3f gyro = AP::ahrs().get_gyro(); if (fabsf(gyro.z) > AP_OPTICALFLOW_CAL_YAW_MAX_RADS) { return; } // check enough roll or pitch movement and record sample const bool rates_x_sufficient = (fabsf(body_rate.x) >= AP_OPTICALFLOW_CAL_ROLLPITCH_MIN_RADS) && (fabsf(flow_rate.x) >= AP_OPTICALFLOW_CAL_ROLLPITCH_MIN_RADS); if (rates_x_sufficient && (_cal_data[0].num_samples < ARRAY_SIZE(_cal_data[0].samples))) { # if HAL_LOGGING_ENABLED log_sample(0, _cal_data[0].num_samples, flow_rate.x, body_rate.x, los_pred.x); #endif _cal_data[0].samples[_cal_data[0].num_samples].flow_rate = flow_rate.x; _cal_data[0].samples[_cal_data[0].num_samples].body_rate = body_rate.x; _cal_data[0].samples[_cal_data[0].num_samples].los_pred = los_pred.x; _cal_data[0].num_samples++; } const bool rates_y_sufficient = (fabsf(body_rate.y) >= AP_OPTICALFLOW_CAL_ROLLPITCH_MIN_RADS) && (fabsf(flow_rate.y) >= AP_OPTICALFLOW_CAL_ROLLPITCH_MIN_RADS); if (rates_y_sufficient && (_cal_data[1].num_samples < ARRAY_SIZE(_cal_data[1].samples))) { # if HAL_LOGGING_ENABLED log_sample(1, _cal_data[1].num_samples, flow_rate.y, body_rate.y, los_pred.y); #endif _cal_data[1].samples[_cal_data[1].num_samples].flow_rate = flow_rate.y; _cal_data[1].samples[_cal_data[1].num_samples].body_rate = body_rate.y; _cal_data[1].samples[_cal_data[1].num_samples].los_pred = los_pred.y; _cal_data[1].num_samples++; } } // returns true once the sample buffer is full bool AP_OpticalFlow_Calibrator::sample_buffers_full() const { return ((_cal_data[0].num_samples >= ARRAY_SIZE(_cal_data[0].samples)) && (_cal_data[1].num_samples >= ARRAY_SIZE(_cal_data[1].samples))); } // run calibration algorithm for both axis // returns true on success and updates _cal_data[0,1].best_scale and best_scale_fitness bool AP_OpticalFlow_Calibrator::run_calibration() { // run calibration for x and y axis const bool calx_res = calc_scalars(0, _cal_data[0].best_scalar, _cal_data[0].best_scalar_fitness); const bool caly_res = calc_scalars(1, _cal_data[1].best_scalar, _cal_data[1].best_scalar_fitness); return calx_res && caly_res; } // Run Gauss Newton fitting algorithm for all samples of the given axis // returns a scalar and fitness (lower numbers mean a better result) in the arguments provided bool AP_OpticalFlow_Calibrator::calc_scalars(uint8_t axis, float& scalar, float& fitness) { // prefix for reporting const char* prefix_str = "FlowCal:"; const char* axis_str = axis == 0 ? "x" : "y"; // check we have samples // this should never fail because this method should only be called once the sample buffer is full const uint8_t num_samples = _cal_data[axis].num_samples; if (num_samples == 0) { GCS_SEND_TEXT(MAV_SEVERITY_INFO, "%s failed because no samples", prefix_str); return false; } // calculate total absolute residual from all samples float total_abs_residual = 0; for (uint8_t i = 0; i < num_samples; i++) { const sample_t& samplei = _cal_data[axis].samples[i]; total_abs_residual += fabsf(calc_sample_residual(samplei, 1.0)); } // if there are no residuals then scaling is perfect if (is_zero(total_abs_residual)) { scalar = 1.0; fitness = 0; GCS_SEND_TEXT(MAV_SEVERITY_INFO, "%s perfect scalar%s of 1.0", prefix_str, axis_str); return true; } // for each sample calculate the residual and scalar that best reduces the residual float best_scalar_total = 0; for (uint8_t i = 0; i < num_samples; i++) { float sample_best_scalar; const sample_t& samplei = _cal_data[axis].samples[i]; if (!calc_sample_best_scalar(samplei, sample_best_scalar)) { // failed to find the best scalar for a single sample // this should never happen because of checks when capturing samples GCS_SEND_TEXT(MAV_SEVERITY_INFO, "%s failed because of zero flow rate", prefix_str); INTERNAL_ERROR(AP_InternalError::error_t::flow_of_control); return false; } const float sample_residual = calc_sample_residual(samplei, 1.0); best_scalar_total += sample_best_scalar * fabsf(sample_residual) / total_abs_residual; } // check for out of range results if (best_scalar_total < AP_OPTICALFLOW_CAL_SCALE_MIN) { GCS_SEND_TEXT(MAV_SEVERITY_INFO, "%s scalar%s:%4.3f too low (<%3.1f)", prefix_str, axis_str, (double)best_scalar_total, (double)AP_OPTICALFLOW_CAL_SCALE_MIN); return false; } if (best_scalar_total > AP_OPTICALFLOW_CAL_SCALE_MAX) { GCS_SEND_TEXT(MAV_SEVERITY_INFO, "%s scalar%s:%4.3f too high (>%3.1f)", prefix_str, axis_str, (double)best_scalar_total, (double)AP_OPTICALFLOW_CAL_SCALE_MAX); return false; } // check for poor fitness float fitness_new = calc_mean_squared_residuals(axis, best_scalar_total); if (fitness_new > AP_OPTICALFLOW_CAL_FITNESS_THRESH) { GCS_SEND_TEXT(MAV_SEVERITY_INFO, "%s scalar%s:%4.3f fit:%4.3f too high (>%3.1f)", prefix_str, axis_str, (double)scalar, (double)fitness_new, (double)AP_OPTICALFLOW_CAL_FITNESS_THRESH); return false; } // success if fitness has improved float fitness_orig = calc_mean_squared_residuals(axis, 1.0); if (fitness_new <= fitness_orig) { scalar = best_scalar_total; fitness = fitness_new; GCS_SEND_TEXT(MAV_SEVERITY_INFO, "%s scalar%s:%4.3f fit:%4.2f", prefix_str, axis_str, (double)scalar, (double)fitness); return true; } // failed to find a better scalar than 1.0 scalar = 1.0; fitness = fitness_orig; GCS_SEND_TEXT(MAV_SEVERITY_INFO, "%s no better scalar%s:%4.3f (fit:%4.3f > orig:%4.3f)", prefix_str, axis_str, (double)best_scalar_total, (double)fitness_new, (double)fitness_orig); return false; } // calculate a single sample's residual float AP_OpticalFlow_Calibrator::calc_sample_residual(const sample_t& sample, float scalar) const { return (sample.body_rate + ((sample.flow_rate * scalar) - sample.los_pred)); } // calculate the scalar that minimises the residual for a single sample // returns true on success and populates the best_scalar argument bool AP_OpticalFlow_Calibrator::calc_sample_best_scalar(const sample_t& sample, float& best_scalar) const { // if sample's flow_rate is zero scalar has no effect // this should never happen because samples should have been checked before being added if (is_zero(sample.flow_rate)) { return false; } best_scalar = (sample.los_pred - sample.body_rate) / sample.flow_rate; return true; } // calculate mean squared residual for all samples of a single axis (0 or 1) given a scalar parameter float AP_OpticalFlow_Calibrator::calc_mean_squared_residuals(uint8_t axis, float scalar) const { // sanity check axis if (axis >= 2) { return AP_OPTICALFLOW_CAL_RMS_FAILED; } // calculate and sum residuals of each sample float sum = 0.0f; uint16_t num_samples = 0; for (uint8_t i = 0; i < _cal_data[axis].num_samples; i++) { sum += sq(calc_sample_residual(_cal_data[axis].samples[i], scalar)); num_samples++; } // return a huge residual if no samples if (num_samples == 0) { return AP_OPTICALFLOW_CAL_RMS_FAILED; } sum /= num_samples; return sum; } #if HAL_LOGGING_ENABLED // log all samples void AP_OpticalFlow_Calibrator::log_sample(uint8_t axis, uint8_t sample_num, float flow_rate, float body_rate, float los_pred) { // @LoggerMessage: OFCA // @Description: Optical Flow Calibration sample // @Field: TimeUS: Time since system startup // @Field: Axis: Axis (X=0 Y=1) // @Field: Num: Sample number // @Field: FRate: Flow rate // @Field: BRate: Body rate // @Field: LPred: Los pred AP::logger().Write( "OFCA", "TimeUS,Axis,Num,FRate,BRate,LPred", "s#-EEE", "F00000", "QBBfff", AP_HAL::micros64(), (unsigned)axis, (unsigned)sample_num, (double)flow_rate, (double)body_rate, (double)los_pred); } #endif // HAL_LOGGING_ENABLED #endif // AP_OPTICALFLOW_CALIBRATOR_ENABLED