/// -*- tab-width: 4; Mode: C++; c-basic-offset: 4; indent-tabs-mode: nil -*- #include #include "AP_InertialSensor.h" #include #include #include #include #include /* enable TIMING_DEBUG to track down scheduling issues with the main loop. Output is on the debug console */ #define TIMING_DEBUG 0 #if TIMING_DEBUG #include #define timing_printf(fmt, args...) do { printf("[timing] " fmt, ##args); } while(0) #else #define timing_printf(fmt, args...) #endif extern const AP_HAL::HAL& hal; #if APM_BUILD_TYPE(APM_BUILD_ArduCopter) #define DEFAULT_GYRO_FILTER 20 #define DEFAULT_ACCEL_FILTER 20 #define DEFAULT_STILL_THRESH 2.5f #elif APM_BUILD_TYPE(APM_BUILD_APMrover2) #define DEFAULT_GYRO_FILTER 10 #define DEFAULT_ACCEL_FILTER 10 #define DEFAULT_STILL_THRESH 0.1f #else #define DEFAULT_GYRO_FILTER 20 #define DEFAULT_ACCEL_FILTER 20 #define DEFAULT_STILL_THRESH 0.1f #endif #define SAMPLE_UNIT 1 // Class level parameters const AP_Param::GroupInfo AP_InertialSensor::var_info[] = { // @Param: PRODUCT_ID // @DisplayName: IMU Product ID // @Description: Which type of IMU is installed (read-only). // @User: Advanced // @Values: 0:Unknown,1:APM1-1280,2:APM1-2560,88:APM2,3:SITL,4:PX4v1,5:PX4v2,256:Flymaple,257:Linux AP_GROUPINFO("PRODUCT_ID", 0, AP_InertialSensor, _product_id, 0), /* The following parameter indexes and reserved from previous use as accel offsets and scaling from before the 16g change in the PX4 backend: ACCSCAL : 1 ACCOFFS : 2 MPU6K_FILTER: 4 ACC2SCAL : 5 ACC2OFFS : 6 ACC3SCAL : 8 ACC3OFFS : 9 CALSENSFRAME : 11 */ // @Param: GYROFFS_X // @DisplayName: Gyro offsets of X axis // @Description: Gyro sensor offsets of X axis. This is setup on each boot during gyro calibrations // @Units: rad/s // @User: Advanced // @Param: GYROFFS_Y // @DisplayName: Gyro offsets of Y axis // @Description: Gyro sensor offsets of Y axis. This is setup on each boot during gyro calibrations // @Units: rad/s // @User: Advanced // @Param: GYROFFS_Z // @DisplayName: Gyro offsets of Z axis // @Description: Gyro sensor offsets of Z axis. This is setup on each boot during gyro calibrations // @Units: rad/s // @User: Advanced AP_GROUPINFO("GYROFFS", 3, AP_InertialSensor, _gyro_offset[0], 0), // @Param: GYR2OFFS_X // @DisplayName: Gyro2 offsets of X axis // @Description: Gyro2 sensor offsets of X axis. This is setup on each boot during gyro calibrations // @Units: rad/s // @User: Advanced // @Param: GYR2OFFS_Y // @DisplayName: Gyro2 offsets of Y axis // @Description: Gyro2 sensor offsets of Y axis. This is setup on each boot during gyro calibrations // @Units: rad/s // @User: Advanced // @Param: GYR2OFFS_Z // @DisplayName: Gyro2 offsets of Z axis // @Description: Gyro2 sensor offsets of Z axis. This is setup on each boot during gyro calibrations // @Units: rad/s // @User: Advanced AP_GROUPINFO("GYR2OFFS", 7, AP_InertialSensor, _gyro_offset[1], 0), // @Param: GYR3OFFS_X // @DisplayName: Gyro3 offsets of X axis // @Description: Gyro3 sensor offsets of X axis. This is setup on each boot during gyro calibrations // @Units: rad/s // @User: Advanced // @Param: GYR3OFFS_Y // @DisplayName: Gyro3 offsets of Y axis // @Description: Gyro3 sensor offsets of Y axis. This is setup on each boot during gyro calibrations // @Units: rad/s // @User: Advanced // @Param: GYR3OFFS_Z // @DisplayName: Gyro3 offsets of Z axis // @Description: Gyro3 sensor offsets of Z axis. This is setup on each boot during gyro calibrations // @Units: rad/s // @User: Advanced AP_GROUPINFO("GYR3OFFS", 10, AP_InertialSensor, _gyro_offset[2], 0), // @Param: ACCSCAL_X // @DisplayName: Accelerometer scaling of X axis // @Description: Accelerometer scaling of X axis. Calculated during acceleration calibration routine // @Range: 0.8 1.2 // @User: Advanced // @Param: ACCSCAL_Y // @DisplayName: Accelerometer scaling of Y axis // @Description: Accelerometer scaling of Y axis Calculated during acceleration calibration routine // @Range: 0.8 1.2 // @User: Advanced // @Param: ACCSCAL_Z // @DisplayName: Accelerometer scaling of Z axis // @Description: Accelerometer scaling of Z axis Calculated during acceleration calibration routine // @Range: 0.8 1.2 // @User: Advanced AP_GROUPINFO("ACCSCAL", 12, AP_InertialSensor, _accel_scale[0], 0), // @Param: ACCOFFS_X // @DisplayName: Accelerometer offsets of X axis // @Description: Accelerometer offsets of X axis. This is setup using the acceleration calibration or level operations // @Units: m/s/s // @Range: -3.5 3.5 // @User: Advanced // @Param: ACCOFFS_Y // @DisplayName: Accelerometer offsets of Y axis // @Description: Accelerometer offsets of Y axis. This is setup using the acceleration calibration or level operations // @Units: m/s/s // @Range: -3.5 3.5 // @User: Advanced // @Param: ACCOFFS_Z // @DisplayName: Accelerometer offsets of Z axis // @Description: Accelerometer offsets of Z axis. This is setup using the acceleration calibration or level operations // @Units: m/s/s // @Range: -3.5 3.5 // @User: Advanced AP_GROUPINFO("ACCOFFS", 13, AP_InertialSensor, _accel_offset[0], 0), // @Param: ACC2SCAL_X // @DisplayName: Accelerometer2 scaling of X axis // @Description: Accelerometer2 scaling of X axis. Calculated during acceleration calibration routine // @Range: 0.8 1.2 // @User: Advanced // @Param: ACC2SCAL_Y // @DisplayName: Accelerometer2 scaling of Y axis // @Description: Accelerometer2 scaling of Y axis Calculated during acceleration calibration routine // @Range: 0.8 1.2 // @User: Advanced // @Param: ACC2SCAL_Z // @DisplayName: Accelerometer2 scaling of Z axis // @Description: Accelerometer2 scaling of Z axis Calculated during acceleration calibration routine // @Range: 0.8 1.2 // @User: Advanced AP_GROUPINFO("ACC2SCAL", 14, AP_InertialSensor, _accel_scale[1], 0), // @Param: ACC2OFFS_X // @DisplayName: Accelerometer2 offsets of X axis // @Description: Accelerometer2 offsets of X axis. This is setup using the acceleration calibration or level operations // @Units: m/s/s // @Range: -3.5 3.5 // @User: Advanced // @Param: ACC2OFFS_Y // @DisplayName: Accelerometer2 offsets of Y axis // @Description: Accelerometer2 offsets of Y axis. This is setup using the acceleration calibration or level operations // @Units: m/s/s // @Range: -3.5 3.5 // @User: Advanced // @Param: ACC2OFFS_Z // @DisplayName: Accelerometer2 offsets of Z axis // @Description: Accelerometer2 offsets of Z axis. This is setup using the acceleration calibration or level operations // @Units: m/s/s // @Range: -3.5 3.5 // @User: Advanced AP_GROUPINFO("ACC2OFFS", 15, AP_InertialSensor, _accel_offset[1], 0), // @Param: ACC3SCAL_X // @DisplayName: Accelerometer3 scaling of X axis // @Description: Accelerometer3 scaling of X axis. Calculated during acceleration calibration routine // @Range: 0.8 1.2 // @User: Advanced // @Param: ACC3SCAL_Y // @DisplayName: Accelerometer3 scaling of Y axis // @Description: Accelerometer3 scaling of Y axis Calculated during acceleration calibration routine // @Range: 0.8 1.2 // @User: Advanced // @Param: ACC3SCAL_Z // @DisplayName: Accelerometer3 scaling of Z axis // @Description: Accelerometer3 scaling of Z axis Calculated during acceleration calibration routine // @Range: 0.8 1.2 // @User: Advanced AP_GROUPINFO("ACC3SCAL", 16, AP_InertialSensor, _accel_scale[2], 0), // @Param: ACC3OFFS_X // @DisplayName: Accelerometer3 offsets of X axis // @Description: Accelerometer3 offsets of X axis. This is setup using the acceleration calibration or level operations // @Units: m/s/s // @Range: -3.5 3.5 // @User: Advanced // @Param: ACC3OFFS_Y // @DisplayName: Accelerometer3 offsets of Y axis // @Description: Accelerometer3 offsets of Y axis. This is setup using the acceleration calibration or level operations // @Units: m/s/s // @Range: -3.5 3.5 // @User: Advanced // @Param: ACC3OFFS_Z // @DisplayName: Accelerometer3 offsets of Z axis // @Description: Accelerometer3 offsets of Z axis. This is setup using the acceleration calibration or level operations // @Units: m/s/s // @Range: -3.5 3.5 // @User: Advanced AP_GROUPINFO("ACC3OFFS", 17, AP_InertialSensor, _accel_offset[2], 0), // @Param: GYRO_FILTER // @DisplayName: Gyro filter cutoff frequency // @Description: Filter cutoff frequency for gyroscopes. This can be set to a lower value to try to cope with very high vibration levels in aircraft. This option takes effect on the next reboot. A value of zero means no filtering (not recommended!) // @Units: Hz // @Range: 0 127 // @User: Advanced AP_GROUPINFO("GYRO_FILTER", 18, AP_InertialSensor, _gyro_filter_cutoff, DEFAULT_GYRO_FILTER), // @Param: ACCEL_FILTER // @DisplayName: Accel filter cutoff frequency // @Description: Filter cutoff frequency for accelerometers. This can be set to a lower value to try to cope with very high vibration levels in aircraft. This option takes effect on the next reboot. A value of zero means no filtering (not recommended!) // @Units: Hz // @Range: 0 127 // @User: Advanced AP_GROUPINFO("ACCEL_FILTER", 19, AP_InertialSensor, _accel_filter_cutoff, DEFAULT_ACCEL_FILTER), // @Param: USE // @DisplayName: Use first IMU for attitude, velocity and position estimates // @Description: Use first IMU for attitude, velocity and position estimates // @Values: 0:Disabled,1:Enabled // @User: Advanced AP_GROUPINFO("USE", 20, AP_InertialSensor, _use[0], 1), // @Param: USE2 // @DisplayName: Use second IMU for attitude, velocity and position estimates // @Description: Use second IMU for attitude, velocity and position estimates // @Values: 0:Disabled,1:Enabled // @User: Advanced AP_GROUPINFO("USE2", 21, AP_InertialSensor, _use[1], 1), // @Param: USE3 // @DisplayName: Use third IMU for attitude, velocity and position estimates // @Description: Use third IMU for attitude, velocity and position estimates // @Values: 0:Disabled,1:Enabled // @User: Advanced AP_GROUPINFO("USE3", 22, AP_InertialSensor, _use[2], 0), // @Param: STILL_THRESH // @DisplayName: Stillness threshold for detecting if we are moving // @Description: Threshold to tolerate vibration to determine if vehicle is motionless. This depends on the frame type and if there is a constant vibration due to motors before launch or after landing. Total motionless is about 0.05. Suggested values: Planes/rover use 0.1, multirotors use 1, tradHeli uses 5 // @Range: 0.05 to 50 // @User: Advanced AP_GROUPINFO("STILL_THRESH", 23, AP_InertialSensor, _still_threshold, DEFAULT_STILL_THRESH), // @Param: GYR_CAL // @DisplayName: Gyro Calibration scheme // @Description: Conrols when automatic gyro calibration is performed // @Values: 0:Never, 1:Start-up only // @User: Advanced AP_GROUPINFO("GYR_CAL", 24, AP_InertialSensor, _gyro_cal_timing, 1), /* NOTE: parameter indexes have gaps above. When adding new parameters check for conflicts carefully */ AP_GROUPEND }; AP_InertialSensor *AP_InertialSensor::_s_instance = nullptr; AP_InertialSensor::AP_InertialSensor() : _gyro_count(0), _accel_count(0), _backend_count(0), _accel(), _gyro(), _board_orientation(ROTATION_NONE), _primary_gyro(0), _primary_accel(0), _hil_mode(false), _calibrating(false), _log_raw_data(false), _backends_detected(false), _dataflash(NULL) { if (_s_instance) { AP_HAL::panic("Too many inertial sensors"); } _s_instance = this; AP_Param::setup_object_defaults(this, var_info); for (uint8_t i=0; istart(); } if (_gyro_count == 0 || _accel_count == 0) { AP_HAL::panic("INS needs at least 1 gyro and 1 accel"); } } /* Find the N instance of the backend that has already been successfully detected */ AP_InertialSensor_Backend *AP_InertialSensor::_find_backend(int16_t backend_id, uint8_t instance) { assert(_backends_detected); uint8_t found = 0; for (uint8_t i = 0; i < _backend_count; i++) { int16_t id = _backends[i]->get_id(); if (id < 0 || id != backend_id) continue; if (instance == found) { return _backends[i]; } else { found++; } } return nullptr; } void AP_InertialSensor::init(Sample_rate sample_rate) { // remember the sample rate _sample_rate = sample_rate; if (_gyro_count == 0 && _accel_count == 0) { _start_backends(); } // initialise accel scale if need be. This is needed as we can't // give non-zero default values for vectors in AP_Param for (uint8_t i=0; idevice(AP_HAL::SPIDevice_MPU9250))); #elif HAL_INS_DEFAULT == HAL_INS_FLYMAPLE _add_backend(AP_InertialSensor_Flymaple::detect(*this)); #elif HAL_INS_DEFAULT == HAL_INS_LSM9DS0 _add_backend(AP_InertialSensor_LSM9DS0::detect(*this)); #elif HAL_INS_DEFAULT == HAL_INS_L3G4200D _add_backend(AP_InertialSensor_L3G4200D::detect(*this)); #elif HAL_INS_DEFAULT == HAL_INS_RASPILOT //_add_backend(AP_InertialSensor_L3GD20::detect); //_add_backend(AP_InertialSensor_LSM303D::detect); _add_backend(AP_InertialSensor_MPU6000::detect_spi(*this)); #elif HAL_INS_DEFAULT == HAL_INS_MPU9250_I2C _add_backend(AP_InertialSensor_MPU9250::detect_i2c(*this, HAL_INS_MPU9250_I2C_POINTER, HAL_INS_MPU9250_I2C_ADDR)); #else #error Unrecognised HAL_INS_TYPE setting #endif if (_backend_count == 0) { AP_HAL::panic("No INS backends available"); } // set the product ID to the ID of the first backend _product_id.set(_backends[0]->product_id()); } /* _calculate_trim - calculates the x and y trim angles. The accel_sample must be correctly scaled, offset and oriented for the board */ bool AP_InertialSensor::_calculate_trim(const Vector3f &accel_sample, float& trim_roll, float& trim_pitch) { trim_pitch = atan2f(accel_sample.x, pythagorous2(accel_sample.y, accel_sample.z)); trim_roll = atan2f(-accel_sample.y, -accel_sample.z); if (fabsf(trim_roll) > radians(10) || fabsf(trim_pitch) > radians(10)) { hal.console->println("trim over maximum of 10 degrees"); return false; } hal.console->printf("Trim OK: roll=%.2f pitch=%.2f\n", (double)degrees(trim_roll), (double)degrees(trim_pitch)); return true; } // calibrate_accel - perform accelerometer calibration including providing user // instructions and feedback Gauss-Newton accel calibration routines borrowed // from Rolfe Schmidt blog post describing the method: // http://chionophilous.wordpress.com/2011/10/24/accelerometer-calibration-iv-1-implementing-gauss-newton-on-an-atmega/ // original sketch available at // http://rolfeschmidt.com/mathtools/skimetrics/adxl_gn_calibration.pde bool AP_InertialSensor::calibrate_accel(AP_InertialSensor_UserInteract* interact, float &trim_roll, float &trim_pitch) { uint8_t num_accels = min(get_accel_count(), INS_MAX_INSTANCES); Vector3f samples[INS_MAX_INSTANCES][6]; Vector3f new_offsets[INS_MAX_INSTANCES]; Vector3f new_scaling[INS_MAX_INSTANCES]; Vector3f orig_offset[INS_MAX_INSTANCES]; Vector3f orig_scale[INS_MAX_INSTANCES]; uint8_t num_ok = 0; // exit immediately if calibration is already in progress if (_calibrating) { return false; } _calibrating = true; /* we do the accel calibration with no board rotation. This avoids having to rotate readings during the calibration */ enum Rotation saved_orientation = _board_orientation; _board_orientation = ROTATION_NONE; for (uint8_t k=0; kprintf( "Place vehicle %s and press any key.\n", msg); // wait for user input if (!interact->blocking_read()) { //No need to use interact->printf for an error, blocking_read does this when it fails goto failed; } const uint8_t update_dt_milliseconds = (uint8_t)(1000.0f/get_sample_rate()+0.5f); // wait 100ms for ins filter to rise for (uint8_t k=0; k<100/update_dt_milliseconds; k++) { wait_for_sample(); update(); hal.scheduler->delay(update_dt_milliseconds); } uint32_t num_samples = 0; while (num_samples < 400/update_dt_milliseconds) { wait_for_sample(); // read samples from ins update(); // capture sample for (uint8_t k=0; k 0) { samp /= _delta_velocity_dt[k]; } else { samp = get_accel(k); } samples[k][i] += samp; if (!get_accel_health(k)) { interact->printf("accel[%u] not healthy", (unsigned)k); goto failed; } } hal.scheduler->delay(update_dt_milliseconds); num_samples++; } for (uint8_t k=0; kprintf("Insufficient accel range"); continue; } bool success = _calibrate_accel(samples[k], new_offsets[k], new_scaling[k], _accel_max_abs_offsets[k], saved_orientation); interact->printf("Offsets[%u]: %.2f %.2f %.2f\n", (unsigned)k, (double)new_offsets[k].x, (double)new_offsets[k].y, (double)new_offsets[k].z); interact->printf("Scaling[%u]: %.2f %.2f %.2f\n", (unsigned)k, (double)new_scaling[k].x, (double)new_scaling[k].y, (double)new_scaling[k].z); if (success) num_ok++; } if (num_ok == num_accels) { interact->printf("Calibration successful\n"); for (uint8_t k=0; kprintf("Calibration FAILED\n"); // restore original scaling and offsets for (uint8_t k=0; k= get_accel_count()) { return 0; } return _accel_clip_count[instance]; } // get_gyro_health_all - return true if all gyros are healthy bool AP_InertialSensor::get_gyro_health_all(void) const { for (uint8_t i=0; i 0); } // gyro_calibration_ok_all - returns true if all gyros were calibrated successfully bool AP_InertialSensor::gyro_calibrated_ok_all() const { for (uint8_t i=0; i 0); } // return true if gyro instance should be used (must be healthy and have it's use parameter set to 1) bool AP_InertialSensor::use_gyro(uint8_t instance) const { if (instance >= INS_MAX_INSTANCES) { return false; } return (get_gyro_health(instance) && _use[instance]); } // get_accel_health_all - return true if all accels are healthy bool AP_InertialSensor::get_accel_health_all(void) const { for (uint8_t i=0; i 0); } /* calculate the trim_roll and trim_pitch. This is used for redoing the trim without needing a full accel cal */ bool AP_InertialSensor::calibrate_trim(float &trim_roll, float &trim_pitch) { Vector3f level_sample; // exit immediately if calibration is already in progress if (_calibrating) { return false; } _calibrating = true; const uint8_t update_dt_milliseconds = (uint8_t)(1000.0f/get_sample_rate()+0.5f); // wait 100ms for ins filter to rise for (uint8_t k=0; k<100/update_dt_milliseconds; k++) { wait_for_sample(); update(); hal.scheduler->delay(update_dt_milliseconds); } uint32_t num_samples = 0; while (num_samples < 400/update_dt_milliseconds) { wait_for_sample(); // read samples from ins update(); // capture sample Vector3f samp; samp = get_accel(0); level_sample += samp; if (!get_accel_health(0)) { goto failed; } hal.scheduler->delay(update_dt_milliseconds); num_samples++; } level_sample /= num_samples; if (!_calculate_trim(level_sample, trim_roll, trim_pitch)) { goto failed; } _calibrating = false; return true; failed: _calibrating = false; return false; } /* check if the accelerometers are calibrated in 3D and that current number of accels matched number when calibrated */ bool AP_InertialSensor::accel_calibrated_ok_all() const { // calibration is not applicable for HIL mode if (_hil_mode) return true; // check each accelerometer has offsets saved for (uint8_t i=0; i= INS_MAX_INSTANCES) { return false; } return (get_accel_health(instance) && _use[instance]); } void AP_InertialSensor::_init_gyro() { uint8_t num_gyros = min(get_gyro_count(), INS_MAX_INSTANCES); Vector3f last_average[INS_MAX_INSTANCES], best_avg[INS_MAX_INSTANCES]; Vector3f new_gyro_offset[INS_MAX_INSTANCES]; float best_diff[INS_MAX_INSTANCES]; bool converged[INS_MAX_INSTANCES]; // exit immediately if calibration is already in progress if (_calibrating) { return; } // record we are calibrating _calibrating = true; // flash leds to tell user to keep the IMU still AP_Notify::flags.initialising = true; // cold start hal.console->print("Init Gyro"); /* we do the gyro calibration with no board rotation. This avoids having to rotate readings during the calibration */ enum Rotation saved_orientation = _board_orientation; _board_orientation = ROTATION_NONE; // remove existing gyro offsets for (uint8_t k=0; kdelay(5); update(); } // the strategy is to average 50 points over 0.5 seconds, then do it // again and see if the 2nd average is within a small margin of // the first uint8_t num_converged = 0; // we try to get a good calibration estimate for up to 30 seconds // if the gyros are stable, we should get it in 1 second for (int16_t j = 0; j <= 30*4 && num_converged < num_gyros; j++) { Vector3f gyro_sum[INS_MAX_INSTANCES], gyro_avg[INS_MAX_INSTANCES], gyro_diff[INS_MAX_INSTANCES]; Vector3f accel_start; float diff_norm[INS_MAX_INSTANCES]; uint8_t i; memset(diff_norm, 0, sizeof(diff_norm)); hal.console->print("*"); for (uint8_t k=0; kdelay(5); } Vector3f accel_diff = get_accel(0) - accel_start; if (accel_diff.length() > 0.2f) { // the accelerometers changed during the gyro sum. Skip // this sample. This copes with doing gyro cal on a // steadily moving platform. The value 0.2 corresponds // with around 5 degrees/second of rotation. continue; } for (uint8_t k=0; kprintln(); for (uint8_t k=0; kprintf("gyro[%u] did not converge: diff=%f dps\n", (unsigned)k, (double)ToDeg(best_diff[k])); _gyro_offset[k] = best_avg[k]; // flag calibration as failed for this gyro _gyro_cal_ok[k] = false; } else { _gyro_cal_ok[k] = true; _gyro_offset[k] = new_gyro_offset[k]; } } // restore orientation _board_orientation = saved_orientation; // record calibration complete _calibrating = false; // stop flashing leds AP_Notify::flags.initialising = false; } /* check that the samples used for accel calibration have a sufficient range on each axis. The sphere fit in _calibrate_accel() can produce bad offsets and scaling factors if the range of input data is insufficient. We rotate each sample in the check to body frame to cope with 45 board orientations which could result in smaller ranges. The sample inputs are in sensor frame */ bool AP_InertialSensor::_check_sample_range(const Vector3f accel_sample[6], enum Rotation rotation, AP_InertialSensor_UserInteract* interact) { // we want at least 12 m/s/s range on all axes. This should be // very easy to achieve, and guarantees the accels have been // exposed to a good range of data const float min_range = 12.0f; Vector3f min_sample, max_sample; // start with first sample min_sample = accel_sample[0]; min_sample.rotate(rotation); max_sample = min_sample; for (uint8_t s=1; s<6; s++) { Vector3f sample = accel_sample[s]; sample.rotate(rotation); for (uint8_t i=0; i<3; i++) { if (sample[i] < min_sample[i]) { min_sample[i] = sample[i]; } if (sample[i] > max_sample[i]) { max_sample[i] = sample[i]; } } } Vector3f range = max_sample - min_sample; interact->printf("AccelRange: %.1f %.1f %.1f", (double)range.x, (double)range.y, (double)range.z); bool ok = (range.x >= min_range && range.y >= min_range && range.z >= min_range); return ok; } // _calibrate_model - perform low level accel calibration // accel_sample are accelerometer samples collected in 6 different positions // accel_offsets are output from the calibration routine // accel_scale are output from the calibration routine // returns true if successful bool AP_InertialSensor::_calibrate_accel(const Vector3f accel_sample[6], Vector3f& accel_offsets, Vector3f& accel_scale, float max_abs_offsets, enum Rotation rotation) { int16_t i; int16_t num_iterations = 0; float eps = 0.000000001f; float change = 100.0f; float data[3]; float beta[6]; float delta[6]; float ds[6]; float JS[6][6]; bool success = true; // reset beta[0] = beta[1] = beta[2] = 0; beta[3] = beta[4] = beta[5] = 1.0f/GRAVITY_MSS; while( num_iterations < 20 && change > eps ) { num_iterations++; _calibrate_reset_matrices(ds, JS); for( i=0; i<6; i++ ) { data[0] = accel_sample[i].x; data[1] = accel_sample[i].y; data[2] = accel_sample[i].z; _calibrate_update_matrices(ds, JS, beta, data); } _calibrate_find_delta(ds, JS, delta); change = delta[0]*delta[0] + delta[0]*delta[0] + delta[1]*delta[1] + delta[2]*delta[2] + delta[3]*delta[3] / (beta[3]*beta[3]) + delta[4]*delta[4] / (beta[4]*beta[4]) + delta[5]*delta[5] / (beta[5]*beta[5]); for( i=0; i<6; i++ ) { beta[i] -= delta[i]; } } // copy results out accel_scale.x = beta[3] * GRAVITY_MSS; accel_scale.y = beta[4] * GRAVITY_MSS; accel_scale.z = beta[5] * GRAVITY_MSS; accel_offsets.x = beta[0] * accel_scale.x; accel_offsets.y = beta[1] * accel_scale.y; accel_offsets.z = beta[2] * accel_scale.z; // sanity check scale if( accel_scale.is_nan() || fabsf(accel_scale.x-1.0f) > 0.1f || fabsf(accel_scale.y-1.0f) > 0.1f || fabsf(accel_scale.z-1.0f) > 0.1f ) { success = false; } if (accel_offsets.is_nan() || fabsf(accel_offsets.x) > max_abs_offsets || fabsf(accel_offsets.y) > max_abs_offsets || fabsf(accel_offsets.z) > max_abs_offsets) { success = false; } // return success or failure return success; } void AP_InertialSensor::_calibrate_update_matrices(float dS[6], float JS[6][6], float beta[6], float data[3]) { int16_t j, k; float dx, b; float residual = 1.0f; float jacobian[6]; for( j=0; j<3; j++ ) { b = beta[3+j]; dx = (float)data[j] - beta[j]; residual -= b*b*dx*dx; jacobian[j] = 2.0f*b*b*dx; jacobian[3+j] = -2.0f*b*dx*dx; } for( j=0; j<6; j++ ) { dS[j] += jacobian[j]*residual; for( k=0; k<6; k++ ) { JS[j][k] += jacobian[j]*jacobian[k]; } } } // _calibrate_reset_matrices - clears matrices void AP_InertialSensor::_calibrate_reset_matrices(float dS[6], float JS[6][6]) { int16_t j,k; for( j=0; j<6; j++ ) { dS[j] = 0.0f; for( k=0; k<6; k++ ) { JS[j][k] = 0.0f; } } } void AP_InertialSensor::_calibrate_find_delta(float dS[6], float JS[6][6], float delta[6]) { //Solve 6-d matrix equation JS*x = dS //first put in upper triangular form int16_t i,j,k; float mu; //make upper triangular for( i=0; i<6; i++ ) { //eliminate all nonzero entries below JS[i][i] for( j=i+1; j<6; j++ ) { mu = JS[i][j]/JS[i][i]; if( !is_zero(mu) ) { dS[j] -= mu*dS[i]; for( k=j; k<6; k++ ) { JS[k][j] -= mu*JS[k][i]; } } } } //back-substitute for( i=5; i>=0; i-- ) { dS[i] /= JS[i][i]; JS[i][i] = 1.0f; for( j=0; jupdate(); } // clear accumulators for (uint8_t i = 0; i < INS_MAX_INSTANCES; i++) { _delta_velocity_acc[i].zero(); _delta_velocity_acc_dt[i] = 0; _delta_angle_acc[i].zero(); } // adjust health status if a sensor has a non-zero error count // but another sensor doesn't. bool have_zero_accel_error_count = false; bool have_zero_gyro_error_count = false; for (uint8_t i=0; idelay_microseconds_boost(wait_usec); uint32_t now2 = AP_HAL::micros(); if (now2+100 < _next_sample_usec) { timing_printf("shortsleep %u\n", (unsigned)(_next_sample_usec-now2)); } if (now2 > _next_sample_usec+400) { timing_printf("longsleep %u wait_usec=%u\n", (unsigned)(now2-_next_sample_usec), (unsigned)wait_usec); } _next_sample_usec += _sample_period_usec; } else if (now - _next_sample_usec < _sample_period_usec/8) { // we've overshot, but only by a small amount, keep on // schedule with no delay timing_printf("overshoot1 %u\n", (unsigned)(now-_next_sample_usec)); _next_sample_usec += _sample_period_usec; } else { // we've overshot by a larger amount, re-zero scheduling with // no delay timing_printf("overshoot2 %u\n", (unsigned)(now-_next_sample_usec)); _next_sample_usec = now + _sample_period_usec; } check_sample: if (!_hil_mode) { // we also wait for at least one backend to have a sample of both // accel and gyro. This normally completes immediately. bool gyro_available = false; bool accel_available = false; while (!gyro_available || !accel_available) { for (uint8_t i=0; i<_backend_count; i++) { _backends[i]->accumulate(); } for (uint8_t i=0; idelay_microseconds(100); } } } now = AP_HAL::micros(); if (_hil_mode && _hil.delta_time > 0) { _delta_time = _hil.delta_time; _hil.delta_time = 0; } else { _delta_time = (now - _last_sample_usec) * 1.0e-6f; } _last_sample_usec = now; #if 0 { static uint64_t delta_time_sum; static uint16_t counter; if (delta_time_sum == 0) { delta_time_sum = _sample_period_usec; } delta_time_sum += _delta_time * 1.0e6f; if (counter++ == 400) { counter = 0; hal.console->printf("now=%lu _delta_time_sum=%lu diff=%ld\n", (unsigned long)now, (unsigned long)delta_time_sum, (long)(now - delta_time_sum)); } } #endif _have_sample = true; } /* get delta angles */ bool AP_InertialSensor::get_delta_angle(uint8_t i, Vector3f &delta_angle) const { if (_delta_angle_valid[i]) { delta_angle = _delta_angle[i]; return true; } else if (get_gyro_health(i)) { // provide delta angle from raw gyro, so we use the same code // at higher level delta_angle = get_gyro(i) * get_delta_time(); return true; } return false; } /* get delta velocity if available */ bool AP_InertialSensor::get_delta_velocity(uint8_t i, Vector3f &delta_velocity) const { if (_delta_velocity_valid[i]) { delta_velocity = _delta_velocity[i]; return true; } else if (get_accel_health(i)) { delta_velocity = get_accel(i) * get_delta_time(); return true; } return false; } /* return delta_time for the delta_velocity */ float AP_InertialSensor::get_delta_velocity_dt(uint8_t i) const { if (_delta_velocity_valid[i]) { return _delta_velocity_dt[i]; } return get_delta_time(); } /* support for setting accel and gyro vectors, for use by HIL */ void AP_InertialSensor::set_accel(uint8_t instance, const Vector3f &accel) { if (_accel_count == 0) { // we haven't initialised yet return; } if (instance < INS_MAX_INSTANCES) { _accel[instance] = accel; _accel_healthy[instance] = true; if (_accel_count <= instance) { _accel_count = instance+1; } if (!_accel_healthy[_primary_accel]) { _primary_accel = instance; } } } void AP_InertialSensor::set_gyro(uint8_t instance, const Vector3f &gyro) { if (_gyro_count == 0) { // we haven't initialised yet return; } if (instance < INS_MAX_INSTANCES) { _gyro[instance] = gyro; _gyro_healthy[instance] = true; if (_gyro_count <= instance) { _gyro_count = instance+1; _gyro_cal_ok[instance] = true; } if (!_accel_healthy[_primary_accel]) { _primary_accel = instance; } } } /* set delta time for next ins.update() */ void AP_InertialSensor::set_delta_time(float delta_time) { _hil.delta_time = delta_time; } /* set delta velocity for next update */ void AP_InertialSensor::set_delta_velocity(uint8_t instance, float deltavt, const Vector3f &deltav) { if (instance < INS_MAX_INSTANCES) { _delta_velocity_valid[instance] = true; _delta_velocity[instance] = deltav; _delta_velocity_dt[instance] = deltavt; } } /* set delta angle for next update */ void AP_InertialSensor::set_delta_angle(uint8_t instance, const Vector3f &deltaa) { if (instance < INS_MAX_INSTANCES) { _delta_angle_valid[instance] = true; _delta_angle[instance] = deltaa; } } /* * Get an AuxiliaryBus of N @instance of backend identified by @backend_id */ AuxiliaryBus *AP_InertialSensor::get_auxiliary_bus(int16_t backend_id, uint8_t instance) { detect_backends(); AP_InertialSensor_Backend *backend = _find_backend(backend_id, instance); if (backend == NULL) return NULL; return backend->get_auxiliary_bus(); } // calculate vibration levels and check for accelerometer clipping (called by a backends) void AP_InertialSensor::calc_vibration_and_clipping(uint8_t instance, const Vector3f &accel, float dt) { // check for clipping if (fabsf(accel.x) > AP_INERTIAL_SENSOR_ACCEL_CLIP_THRESH_MSS || fabsf(accel.y) > AP_INERTIAL_SENSOR_ACCEL_CLIP_THRESH_MSS || fabsf(accel.z) > AP_INERTIAL_SENSOR_ACCEL_CLIP_THRESH_MSS) { _accel_clip_count[instance]++; } // calculate vibration levels if (instance < INS_VIBRATION_CHECK_INSTANCES) { // filter accel at 5hz Vector3f accel_filt = _accel_vibe_floor_filter[instance].apply(accel, dt); // calc difference from this sample and 5hz filtered value, square and filter at 2hz Vector3f accel_diff = (accel - accel_filt); accel_diff.x *= accel_diff.x; accel_diff.y *= accel_diff.y; accel_diff.z *= accel_diff.z; _accel_vibe_filter[instance].apply(accel_diff, dt); } } // retrieve latest calculated vibration levels Vector3f AP_InertialSensor::get_vibration_levels(uint8_t instance) const { Vector3f vibe; if (instance < INS_VIBRATION_CHECK_INSTANCES) { vibe = _accel_vibe_filter[instance].get(); vibe.x = safe_sqrt(vibe.x); vibe.y = safe_sqrt(vibe.y); vibe.z = safe_sqrt(vibe.z); } return vibe; } // check for vibration movement. Return true if all axis show nearly zero movement bool AP_InertialSensor::is_still() { Vector3f vibe = get_vibration_levels(); return (vibe.x < _still_threshold) && (vibe.y < _still_threshold) && (vibe.z < _still_threshold); }