diff options
20 files changed, 3714 insertions, 775 deletions
diff --git a/ROMFS/px4fmu_common/init.d/rcS b/ROMFS/px4fmu_common/init.d/rcS index 6d06f897a..f70e0ed77 100644 --- a/ROMFS/px4fmu_common/init.d/rcS +++ b/ROMFS/px4fmu_common/init.d/rcS @@ -428,11 +428,10 @@ then # sh /etc/init.d/rc.sensors - if [ $HIL == no ] - then - echo "[init] Start logging" - sh /etc/init.d/rc.logging - fi + # + # Start logging in all modes, including HIL + # + sh /etc/init.d/rc.logging if [ $GPS == yes ] then diff --git a/src/drivers/mpu6000/mpu6000.cpp b/src/drivers/mpu6000/mpu6000.cpp index 321fdd173..0edec3d0e 100644 --- a/src/drivers/mpu6000/mpu6000.cpp +++ b/src/drivers/mpu6000/mpu6000.cpp @@ -544,7 +544,7 @@ void MPU6000::reset() write_reg(MPUREG_USER_CTRL, BIT_I2C_IF_DIS); irqrestore(state); - up_udelay(1000); + usleep(1000); // SAMPLE RATE _set_sample_rate(_sample_rate); diff --git a/src/modules/commander/commander.cpp b/src/modules/commander/commander.cpp index 1535967b1..03f5e83e2 100644 --- a/src/modules/commander/commander.cpp +++ b/src/modules/commander/commander.cpp @@ -1590,7 +1590,6 @@ set_main_state_rc(struct vehicle_status_s *status, struct manual_control_setpoin switch (sp_man->mode_switch) { case SWITCH_POS_NONE: res = TRANSITION_NOT_CHANGED; - warnx("NONE"); break; case SWITCH_POS_OFF: // MANUAL diff --git a/src/modules/ekf_att_pos_estimator/ekf_att_pos_estimator_main.cpp b/src/modules/ekf_att_pos_estimator/ekf_att_pos_estimator_main.cpp index ac99e658d..e4f805dc0 100644 --- a/src/modules/ekf_att_pos_estimator/ekf_att_pos_estimator_main.cpp +++ b/src/modules/ekf_att_pos_estimator/ekf_att_pos_estimator_main.cpp @@ -49,11 +49,11 @@ #include <math.h> #include <poll.h> #include <time.h> -#include <drivers/drv_hrt.h> +#include <float.h> #define SENSOR_COMBINED_SUB - +#include <drivers/drv_hrt.h> #include <drivers/drv_gyro.h> #include <drivers/drv_accel.h> #include <drivers/drv_mag.h> @@ -83,7 +83,7 @@ #include <mathlib/mathlib.h> #include <mavlink/mavlink_log.h> -#include "estimator.h" +#include "estimator_23states.h" @@ -96,7 +96,6 @@ extern "C" __EXPORT int ekf_att_pos_estimator_main(int argc, char *argv[]); __EXPORT uint32_t millis(); -static uint64_t last_run = 0; static uint64_t IMUmsec = 0; static const uint64_t FILTER_INIT_DELAY = 1 * 1000 * 1000; @@ -121,7 +120,7 @@ public: /** * Start the sensors task. * - * @return OK on success. + * @return OK on success. */ int start(); @@ -135,6 +134,20 @@ public: */ int trip_nan(); + /** + * Enable logging. + * + * @param enable Set to true to enable logging, false to disable + */ + int enable_logging(bool enable); + + /** + * Set debug level. + * + * @param debug Desired debug level - 0 to disable. + */ + int set_debuglevel(unsigned debug) { _debug = debug; return 0; } + private: bool _task_should_exit; /**< if true, sensor task should exit */ @@ -184,24 +197,28 @@ private: struct map_projection_reference_s _pos_ref; float _baro_ref; /**< barometer reference altitude */ - float _baro_gps_offset; /**< offset between GPS and baro */ + float _baro_ref_offset; /**< offset between initial baro reference and GPS init baro altitude */ + float _baro_gps_offset; /**< offset between baro altitude (at GPS init time) and GPS altitude */ - perf_counter_t _loop_perf; /**< loop performance counter */ + perf_counter_t _loop_perf; ///< loop performance counter perf_counter_t _perf_gyro; ///<local performance counter for gyro updates - perf_counter_t _perf_accel; ///<local performance counter for accel updates perf_counter_t _perf_mag; ///<local performance counter for mag updates perf_counter_t _perf_gps; ///<local performance counter for gps updates perf_counter_t _perf_baro; ///<local performance counter for baro updates perf_counter_t _perf_airspeed; ///<local performance counter for airspeed updates + perf_counter_t _perf_reset; ///<local performance counter for filter resets - bool _initialized; bool _baro_init; bool _gps_initialized; - uint64_t _gps_start_time; - uint64_t _filter_start_time; + hrt_abstime _gps_start_time; + hrt_abstime _filter_start_time; + hrt_abstime _last_sensor_timestamp; + hrt_abstime _last_run; bool _gyro_valid; bool _accel_valid; bool _mag_valid; + bool _ekf_logging; ///< log EKF state + unsigned _debug; ///< debug level - default 0 int _mavlink_fd; @@ -275,9 +292,16 @@ private: static void task_main_trampoline(int argc, char *argv[]); /** - * Main sensor collection task. + * Main filter task. */ void task_main(); + + /** + * Check filter sanity state + * + * @return zero if ok, non-zero for a filter error condition. + */ + int check_filter_state(); }; namespace estimator @@ -342,24 +366,26 @@ FixedwingEstimator::FixedwingEstimator() : #endif _baro_ref(0.0f), + _baro_ref_offset(0.0f), _baro_gps_offset(0.0f), /* performance counters */ - _loop_perf(perf_alloc(PC_COUNT, "ekf_att_pos_estimator")), - _perf_gyro(perf_alloc(PC_COUNT, "ekf_att_pos_gyro_upd")), - _perf_accel(perf_alloc(PC_COUNT, "ekf_att_pos_accel_upd")), - _perf_mag(perf_alloc(PC_COUNT, "ekf_att_pos_mag_upd")), - _perf_gps(perf_alloc(PC_COUNT, "ekf_att_pos_gps_upd")), - _perf_baro(perf_alloc(PC_COUNT, "ekf_att_pos_baro_upd")), - _perf_airspeed(perf_alloc(PC_COUNT, "ekf_att_pos_aspd_upd")), + _loop_perf(perf_alloc(PC_ELAPSED, "ekf_att_pos_estimator")), + _perf_gyro(perf_alloc(PC_INTERVAL, "ekf_att_pos_gyro_upd")), + _perf_mag(perf_alloc(PC_INTERVAL, "ekf_att_pos_mag_upd")), + _perf_gps(perf_alloc(PC_INTERVAL, "ekf_att_pos_gps_upd")), + _perf_baro(perf_alloc(PC_INTERVAL, "ekf_att_pos_baro_upd")), + _perf_airspeed(perf_alloc(PC_INTERVAL, "ekf_att_pos_aspd_upd")), + _perf_reset(perf_alloc(PC_COUNT, "ekf_att_pos_reset")), /* states */ - _initialized(false), _baro_init(false), _gps_initialized(false), _gyro_valid(false), _accel_valid(false), _mag_valid(false), + _ekf_logging(true), + _debug(0), _mavlink_fd(-1), _ekf(nullptr), _velocity_xy_filtered(0.0f), @@ -367,7 +393,7 @@ FixedwingEstimator::FixedwingEstimator() : _airspeed_filtered(0.0f) { - last_run = hrt_absolute_time(); + _last_run = hrt_absolute_time(); _parameter_handles.vel_delay_ms = param_find("PE_VEL_DELAY_MS"); _parameter_handles.pos_delay_ms = param_find("PE_POS_DELAY_MS"); @@ -451,10 +477,20 @@ FixedwingEstimator::~FixedwingEstimator() } while (_estimator_task != -1); } + delete _ekf; + estimator::g_estimator = nullptr; } int +FixedwingEstimator::enable_logging(bool logging) +{ + _ekf_logging = logging; + + return 0; +} + +int FixedwingEstimator::parameters_update() { @@ -512,6 +548,151 @@ FixedwingEstimator::vehicle_status_poll() } } +int +FixedwingEstimator::check_filter_state() +{ + /* + * CHECK IF THE INPUT DATA IS SANE + */ + + struct ekf_status_report ekf_report; + + int check = _ekf->CheckAndBound(&ekf_report); + + const char* ekfname = "att pos estimator: "; + + switch (check) { + case 0: + /* all ok */ + break; + case 1: + { + const char* str = "NaN in states, resetting"; + warnx("%s", str); + mavlink_log_critical(_mavlink_fd, "%s%s", ekfname, str); + break; + } + case 2: + { + const char* str = "stale IMU data, resetting"; + warnx("%s", str); + mavlink_log_critical(_mavlink_fd, "%s%s", ekfname, str); + break; + } + case 3: + { + const char* str = "switching to dynamic state"; + warnx("%s", str); + mavlink_log_info(_mavlink_fd, "%s%s", ekfname, str); + break; + } + case 4: + { + const char* str = "excessive gyro offsets"; + warnx("%s", str); + mavlink_log_info(_mavlink_fd, "%s%s", ekfname, str); + break; + } + case 5: + { + const char* str = "GPS velocity divergence"; + warnx("%s", str); + mavlink_log_info(_mavlink_fd, "%s%s", ekfname, str); + break; + } + case 6: + { + const char* str = "excessive covariances"; + warnx("%s", str); + mavlink_log_info(_mavlink_fd, "%s%s", ekfname, str); + break; + } + + default: + { + const char* str = "unknown reset condition"; + warnx("%s", str); + mavlink_log_critical(_mavlink_fd, "%s%s", ekfname, str); + } + } + + struct estimator_status_report rep; + memset(&rep, 0, sizeof(rep)); + + // If error flag is set, we got a filter reset + if (check && ekf_report.error) { + + // Count the reset condition + perf_count(_perf_reset); + + } else if (_ekf_logging) { + _ekf->GetFilterState(&ekf_report); + } + + if (_ekf_logging || check) { + rep.timestamp = hrt_absolute_time(); + + rep.nan_flags |= (((uint8_t)ekf_report.angNaN) << 0); + rep.nan_flags |= (((uint8_t)ekf_report.summedDelVelNaN) << 1); + rep.nan_flags |= (((uint8_t)ekf_report.KHNaN) << 2); + rep.nan_flags |= (((uint8_t)ekf_report.KHPNaN) << 3); + rep.nan_flags |= (((uint8_t)ekf_report.PNaN) << 4); + rep.nan_flags |= (((uint8_t)ekf_report.covarianceNaN) << 5); + rep.nan_flags |= (((uint8_t)ekf_report.kalmanGainsNaN) << 6); + rep.nan_flags |= (((uint8_t)ekf_report.statesNaN) << 7); + + rep.health_flags |= (((uint8_t)ekf_report.velHealth) << 0); + rep.health_flags |= (((uint8_t)ekf_report.posHealth) << 1); + rep.health_flags |= (((uint8_t)ekf_report.hgtHealth) << 2); + rep.health_flags |= (((uint8_t)!ekf_report.gyroOffsetsExcessive) << 3); + + rep.timeout_flags |= (((uint8_t)ekf_report.velTimeout) << 0); + rep.timeout_flags |= (((uint8_t)ekf_report.posTimeout) << 1); + rep.timeout_flags |= (((uint8_t)ekf_report.hgtTimeout) << 2); + rep.timeout_flags |= (((uint8_t)ekf_report.imuTimeout) << 3); + + if (_debug > 10) { + + if (rep.health_flags < ((1 << 0) | (1 << 1) | (1 << 2) | (1 << 3))) { + warnx("health: VEL:%s POS:%s HGT:%s OFFS:%s", + ((rep.health_flags & (1 << 0)) ? "OK" : "ERR"), + ((rep.health_flags & (1 << 1)) ? "OK" : "ERR"), + ((rep.health_flags & (1 << 2)) ? "OK" : "ERR"), + ((rep.health_flags & (1 << 3)) ? "OK" : "ERR")); + } + + if (rep.timeout_flags) { + warnx("timeout: %s%s%s%s", + ((rep.timeout_flags & (1 << 0)) ? "VEL " : ""), + ((rep.timeout_flags & (1 << 1)) ? "POS " : ""), + ((rep.timeout_flags & (1 << 2)) ? "HGT " : ""), + ((rep.timeout_flags & (1 << 3)) ? "IMU " : "")); + } + } + + // Copy all states or at least all that we can fit + unsigned ekf_n_states = ekf_report.n_states; + unsigned max_states = (sizeof(rep.states) / sizeof(rep.states[0])); + rep.n_states = (ekf_n_states < max_states) ? ekf_n_states : max_states; + + for (unsigned i = 0; i < rep.n_states; i++) { + rep.states[i] = ekf_report.states[i]; + } + + for (unsigned i = 0; i < rep.n_states; i++) { + rep.states[i] = ekf_report.states[i]; + } + + if (_estimator_status_pub > 0) { + orb_publish(ORB_ID(estimator_status), _estimator_status_pub, &rep); + } else { + _estimator_status_pub = orb_advertise(ORB_ID(estimator_status), &rep); + } + } + + return check; +} + void FixedwingEstimator::task_main_trampoline(int argc, char *argv[]) { @@ -528,7 +709,7 @@ FixedwingEstimator::task_main() _filter_start_time = hrt_absolute_time(); if (!_ekf) { - errx(1, "failed allocating EKF filter - out of RAM!"); + errx(1, "OUT OF MEM!"); } /* @@ -556,7 +737,7 @@ FixedwingEstimator::task_main() #else _sensor_combined_sub = orb_subscribe(ORB_ID(sensor_combined)); /* XXX remove this!, BUT increase the data buffer size! */ - orb_set_interval(_sensor_combined_sub, 4); + orb_set_interval(_sensor_combined_sub, 9); #endif /* sets also parameters in the EKF object */ @@ -584,6 +765,13 @@ FixedwingEstimator::task_main() bool newAdsData = false; bool newDataMag = false; + float posNED[3] = {0.0f, 0.0f, 0.0f}; // North, East Down position (m) + + uint64_t last_gps = 0; + _gps.vel_n_m_s = 0.0f; + _gps.vel_e_m_s = 0.0f; + _gps.vel_d_m_s = 0.0f; + while (!_task_should_exit) { /* wait for up to 500ms for data */ @@ -595,7 +783,7 @@ FixedwingEstimator::task_main() /* this is undesirable but not much we can do - might want to flag unhappy status */ if (pret < 0) { - warn("poll error %d, %d", pret, errno); + warn("POLL ERR %d, %d", pret, errno); continue; } @@ -621,8 +809,6 @@ FixedwingEstimator::task_main() bool accel_updated; bool mag_updated; - hrt_abstime last_sensor_timestamp; - perf_count(_perf_gyro); /* Reset baro reference if switching to HIL, reset sensor states */ @@ -646,12 +832,12 @@ FixedwingEstimator::task_main() _baro_init = false; _gps_initialized = false; - last_sensor_timestamp = hrt_absolute_time(); - last_run = last_sensor_timestamp; + _last_sensor_timestamp = hrt_absolute_time(); + _last_run = _last_sensor_timestamp; _ekf->ZeroVariables(); _ekf->dtIMU = 0.01f; - _filter_start_time = last_sensor_timestamp; + _filter_start_time = _last_sensor_timestamp; /* now skip this loop and get data on the next one, which will also re-init the filter */ continue; @@ -669,15 +855,14 @@ FixedwingEstimator::task_main() orb_check(_accel_sub, &accel_updated); if (accel_updated) { - perf_count(_perf_accel); orb_copy(ORB_ID(sensor_accel), _accel_sub, &_accel); } - last_sensor_timestamp = _gyro.timestamp; + _last_sensor_timestamp = _gyro.timestamp; IMUmsec = _gyro.timestamp / 1e3f; - float deltaT = (_gyro.timestamp - last_run) / 1e6f; - last_run = _gyro.timestamp; + float deltaT = (_gyro.timestamp - _last_run) / 1e6f; + _last_run = _gyro.timestamp; /* guard against too large deltaT's */ if (!isfinite(deltaT) || deltaT > 1.0f || deltaT < 0.000001f) { @@ -737,17 +922,17 @@ FixedwingEstimator::task_main() // Copy gyro and accel - last_sensor_timestamp = _sensor_combined.timestamp; + _last_sensor_timestamp = _sensor_combined.timestamp; IMUmsec = _sensor_combined.timestamp / 1e3f; - float deltaT = (_sensor_combined.timestamp - last_run) / 1e6f; + float deltaT = (_sensor_combined.timestamp - _last_run) / 1e6f; /* guard against too large deltaT's */ if (!isfinite(deltaT) || deltaT > 1.0f || deltaT < 0.000001f) { deltaT = 0.01f; } - last_run = _sensor_combined.timestamp; + _last_run = _sensor_combined.timestamp; // Always store data, independent of init status /* fill in last data set */ @@ -765,6 +950,7 @@ FixedwingEstimator::task_main() } _gyro_valid = true; + perf_count(_perf_gyro); } if (accel_updated) { @@ -796,6 +982,8 @@ FixedwingEstimator::task_main() #endif + //warnx("dang: %8.4f %8.4f dvel: %8.4f %8.4f", _ekf->dAngIMU.x, _ekf->dAngIMU.z, _ekf->dVelIMU.x, _ekf->dVelIMU.z); + bool airspeed_updated; orb_check(_airspeed_sub, &airspeed_updated); @@ -815,7 +1003,7 @@ FixedwingEstimator::task_main() if (gps_updated) { - uint64_t last_gps = _gps.timestamp_position; + last_gps = _gps.timestamp_position; orb_copy(ORB_ID(vehicle_gps_position), _gps_sub, &_gps); perf_count(_perf_gps); @@ -883,6 +1071,8 @@ FixedwingEstimator::task_main() warnx("ALT REF INIT"); } + perf_count(_perf_baro); + newHgtData = true; } else { newHgtData = false; @@ -933,127 +1123,39 @@ FixedwingEstimator::task_main() newDataMag = false; } - - /** - * CHECK IF THE INPUT DATA IS SANE + /* + * CHECK IF ITS THE RIGHT TIME TO RUN THINGS ALREADY */ - int check = _ekf->CheckAndBound(); - - const char* ekfname = "[ekf] "; - - switch (check) { - case 0: - /* all ok */ - break; - case 1: - { - const char* str = "NaN in states, resetting"; - warnx("%s", str); - mavlink_log_critical(_mavlink_fd, "%s%s", ekfname, str); - break; - } - case 2: - { - const char* str = "stale IMU data, resetting"; - warnx("%s", str); - mavlink_log_critical(_mavlink_fd, "%s%s", ekfname, str); - break; - } - case 3: - { - const char* str = "switching to dynamic state"; - warnx("%s", str); - mavlink_log_info(_mavlink_fd, "%s%s", ekfname, str); - break; - } - - default: - { - const char* str = "unknown reset condition"; - warnx("%s", str); - mavlink_log_critical(_mavlink_fd, "%s%s", ekfname, str); - } - } - - // warn on fatal resets - if (check == 1) { - warnx("NUMERIC ERROR IN FILTER"); - } - - // If non-zero, we got a filter reset - if (check) { - - struct ekf_status_report ekf_report; - - _ekf->GetLastErrorState(&ekf_report); - - struct estimator_status_report rep; - memset(&rep, 0, sizeof(rep)); - rep.timestamp = hrt_absolute_time(); - - rep.states_nan = ekf_report.statesNaN; - rep.covariance_nan = ekf_report.covarianceNaN; - rep.kalman_gain_nan = ekf_report.kalmanGainsNaN; - - // Copy all states or at least all that we can fit - unsigned i = 0; - unsigned ekf_n_states = (sizeof(ekf_report.states) / sizeof(ekf_report.states[0])); - unsigned max_states = (sizeof(rep.states) / sizeof(rep.states[0])); - rep.n_states = (ekf_n_states < max_states) ? ekf_n_states : max_states; - - while ((i < ekf_n_states) && (i < max_states)) { - - rep.states[i] = ekf_report.states[i]; - i++; - } - - if (_estimator_status_pub > 0) { - orb_publish(ORB_ID(estimator_status), _estimator_status_pub, &rep); - } else { - _estimator_status_pub = orb_advertise(ORB_ID(estimator_status), &rep); - } - - /* set sensors to de-initialized state */ - _gyro_valid = false; - _accel_valid = false; - _mag_valid = false; - - _baro_init = false; - _gps_initialized = false; - last_sensor_timestamp = hrt_absolute_time(); - last_run = last_sensor_timestamp; - - _ekf->ZeroVariables(); - _ekf->dtIMU = 0.01f; - - // Let the system re-initialize itself + if (hrt_elapsed_time(&_filter_start_time) < FILTER_INIT_DELAY) { continue; - } - /** * PART TWO: EXECUTE THE FILTER + * + * We run the filter only once all data has been fetched **/ - if ((hrt_elapsed_time(&_filter_start_time) > FILTER_INIT_DELAY) && _baro_init && _gyro_valid && _accel_valid && _mag_valid) { + if (_baro_init && _gyro_valid && _accel_valid && _mag_valid) { float initVelNED[3]; + /* Initialize the filter first */ if (!_gps_initialized && _gps.fix_type > 2 && _gps.eph < _parameters.pos_stddev_threshold && _gps.epv < _parameters.pos_stddev_threshold) { - initVelNED[0] = _gps.vel_n_m_s; - initVelNED[1] = _gps.vel_e_m_s; - initVelNED[2] = _gps.vel_d_m_s; - // GPS is in scaled integers, convert double lat = _gps.lat / 1.0e7; double lon = _gps.lon / 1.0e7; float gps_alt = _gps.alt / 1e3f; + initVelNED[0] = _gps.vel_n_m_s; + initVelNED[1] = _gps.vel_e_m_s; + initVelNED[2] = _gps.vel_d_m_s; + // Set up height correctly orb_copy(ORB_ID(sensor_baro), _baro_sub, &_baro); - _baro_gps_offset = _baro_ref - _baro.altitude; + _baro_ref_offset = _ekf->states[9]; // this should become zero in the local frame + _baro_gps_offset = _baro.altitude - gps_alt; _ekf->baroHgt = _baro.altitude; _ekf->hgtMea = 1.0f * (_ekf->baroHgt - (_baro_ref)); @@ -1077,10 +1179,13 @@ FixedwingEstimator::task_main() map_projection_init(&_pos_ref, lat, lon); mavlink_log_info(_mavlink_fd, "[ekf] ref: LA %.4f,LO %.4f,ALT %.2f", lat, lon, (double)gps_alt); + + #if 0 warnx("HOME/REF: LA %8.4f,LO %8.4f,ALT %8.2f V: %8.4f %8.4f %8.4f", lat, lon, (double)gps_alt, (double)_ekf->velNED[0], (double)_ekf->velNED[1], (double)_ekf->velNED[2]); - warnx("BARO: %8.4f m / ref: %8.4f m / gps offs: %8.4f m", (double)_ekf->baroHgt, (double)_baro_ref, (double)_baro_gps_offset); + warnx("BARO: %8.4f m / ref: %8.4f m / gps offs: %8.4f m", (double)_ekf->baroHgt, (double)_baro_ref, (double)_baro_ref_offset); warnx("GPS: eph: %8.4f, epv: %8.4f, declination: %8.4f", (double)_gps.eph, (double)_gps.epv, (double)math::degrees(declination)); + #endif _gps_initialized = true; @@ -1089,279 +1194,304 @@ FixedwingEstimator::task_main() initVelNED[0] = 0.0f; initVelNED[1] = 0.0f; initVelNED[2] = 0.0f; - _ekf->posNED[0] = 0.0f; - _ekf->posNED[1] = 0.0f; - _ekf->posNED[2] = 0.0f; - - _ekf->posNE[0] = _ekf->posNED[0]; - _ekf->posNE[1] = _ekf->posNED[1]; + _ekf->posNE[0] = posNED[0]; + _ekf->posNE[1] = posNED[1]; _local_pos.ref_alt = _baro_ref; + _baro_ref_offset = 0.0f; _baro_gps_offset = 0.0f; _ekf->InitialiseFilter(initVelNED, 0.0, 0.0, 0.0f, 0.0f); - } - } - - // If valid IMU data and states initialised, predict states and covariances - if (_ekf->statesInitialised) { - // Run the strapdown INS equations every IMU update - _ekf->UpdateStrapdownEquationsNED(); -#if 0 - // debug code - could be tunred into a filter mnitoring/watchdog function - float tempQuat[4]; - - for (uint8_t j = 0; j <= 3; j++) tempQuat[j] = states[j]; + } else if (_ekf->statesInitialised) { - quat2eul(eulerEst, tempQuat); + // We're apparently initialized in this case now - for (uint8_t j = 0; j <= 2; j++) eulerDif[j] = eulerEst[j] - ahrsEul[j]; + int check = check_filter_state(); - if (eulerDif[2] > pi) eulerDif[2] -= 2 * pi; - - if (eulerDif[2] < -pi) eulerDif[2] += 2 * pi; - -#endif - // store the predicted states for subsequent use by measurement fusion - _ekf->StoreStates(IMUmsec); - // Check if on ground - status is used by covariance prediction - _ekf->OnGroundCheck(); - // sum delta angles and time used by covariance prediction - _ekf->summedDelAng = _ekf->summedDelAng + _ekf->correctedDelAng; - _ekf->summedDelVel = _ekf->summedDelVel + _ekf->dVelIMU; - dt += _ekf->dtIMU; - - // perform a covariance prediction if the total delta angle has exceeded the limit - // or the time limit will be exceeded at the next IMU update - if ((dt >= (_ekf->covTimeStepMax - _ekf->dtIMU)) || (_ekf->summedDelAng.length() > _ekf->covDelAngMax)) { - _ekf->CovariancePrediction(dt); - _ekf->summedDelAng.zero(); - _ekf->summedDelVel.zero(); - dt = 0.0f; - } - - _initialized = true; - } - - // Fuse GPS Measurements - if (newDataGps && _gps_initialized) { - // Convert GPS measurements to Pos NE, hgt and Vel NED - _ekf->velNED[0] = _gps.vel_n_m_s; - _ekf->velNED[1] = _gps.vel_e_m_s; - _ekf->velNED[2] = _gps.vel_d_m_s; - _ekf->calcposNED(_ekf->posNED, _ekf->gpsLat, _ekf->gpsLon, _ekf->gpsHgt, _ekf->latRef, _ekf->lonRef, _ekf->hgtRef); - - _ekf->posNE[0] = _ekf->posNED[0]; - _ekf->posNE[1] = _ekf->posNED[1]; - // set fusion flags - _ekf->fuseVelData = true; - _ekf->fusePosData = true; - // recall states stored at time of measurement after adjusting for delays - _ekf->RecallStates(_ekf->statesAtVelTime, (IMUmsec - _parameters.vel_delay_ms)); - _ekf->RecallStates(_ekf->statesAtPosTime, (IMUmsec - _parameters.pos_delay_ms)); - // run the fusion step - _ekf->FuseVelposNED(); - - } else if (_ekf->statesInitialised) { - // Convert GPS measurements to Pos NE, hgt and Vel NED - _ekf->velNED[0] = 0.0f; - _ekf->velNED[1] = 0.0f; - _ekf->velNED[2] = 0.0f; - _ekf->posNED[0] = 0.0f; - _ekf->posNED[1] = 0.0f; - _ekf->posNED[2] = 0.0f; - - _ekf->posNE[0] = _ekf->posNED[0]; - _ekf->posNE[1] = _ekf->posNED[1]; - // set fusion flags - _ekf->fuseVelData = true; - _ekf->fusePosData = true; - // recall states stored at time of measurement after adjusting for delays - _ekf->RecallStates(_ekf->statesAtVelTime, (IMUmsec - _parameters.vel_delay_ms)); - _ekf->RecallStates(_ekf->statesAtPosTime, (IMUmsec - _parameters.pos_delay_ms)); - // run the fusion step - _ekf->FuseVelposNED(); + if (check) { + // Let the system re-initialize itself + continue; + } - } else { - _ekf->fuseVelData = false; - _ekf->fusePosData = false; - } - if (newHgtData && _ekf->statesInitialised) { - // Could use a blend of GPS and baro alt data if desired - _ekf->hgtMea = 1.0f * (_ekf->baroHgt - _baro_ref); - _ekf->fuseHgtData = true; - // recall states stored at time of measurement after adjusting for delays - _ekf->RecallStates(_ekf->statesAtHgtTime, (IMUmsec - _parameters.height_delay_ms)); - // run the fusion step - _ekf->FuseVelposNED(); + // Run the strapdown INS equations every IMU update + _ekf->UpdateStrapdownEquationsNED(); + #if 0 + // debug code - could be tunred into a filter mnitoring/watchdog function + float tempQuat[4]; - } else { - _ekf->fuseHgtData = false; - } + for (uint8_t j = 0; j <= 3; j++) tempQuat[j] = states[j]; - // Fuse Magnetometer Measurements - if (newDataMag && _ekf->statesInitialised) { - _ekf->fuseMagData = true; - _ekf->RecallStates(_ekf->statesAtMagMeasTime, (IMUmsec - _parameters.mag_delay_ms)); // Assume 50 msec avg delay for magnetometer data + quat2eul(eulerEst, tempQuat); - } else { - _ekf->fuseMagData = false; - } + for (uint8_t j = 0; j <= 2; j++) eulerDif[j] = eulerEst[j] - ahrsEul[j]; - if (_ekf->statesInitialised) _ekf->FuseMagnetometer(); + if (eulerDif[2] > pi) eulerDif[2] -= 2 * pi; - // Fuse Airspeed Measurements - if (newAdsData && _ekf->statesInitialised && _ekf->VtasMeas > 8.0f) { - _ekf->fuseVtasData = true; - _ekf->RecallStates(_ekf->statesAtVtasMeasTime, (IMUmsec - _parameters.tas_delay_ms)); // assume 100 msec avg delay for airspeed data - _ekf->FuseAirspeed(); + if (eulerDif[2] < -pi) eulerDif[2] += 2 * pi; - } else { - _ekf->fuseVtasData = false; - } + #endif + // store the predicted states for subsequent use by measurement fusion + _ekf->StoreStates(IMUmsec); + // Check if on ground - status is used by covariance prediction + _ekf->OnGroundCheck(); + // sum delta angles and time used by covariance prediction + _ekf->summedDelAng = _ekf->summedDelAng + _ekf->correctedDelAng; + _ekf->summedDelVel = _ekf->summedDelVel + _ekf->dVelIMU; + dt += _ekf->dtIMU; + + // perform a covariance prediction if the total delta angle has exceeded the limit + // or the time limit will be exceeded at the next IMU update + if ((dt >= (_ekf->covTimeStepMax - _ekf->dtIMU)) || (_ekf->summedDelAng.length() > _ekf->covDelAngMax)) { + _ekf->CovariancePrediction(dt); + _ekf->summedDelAng.zero(); + _ekf->summedDelVel.zero(); + dt = 0.0f; + } - // Publish results - if (_initialized && (check == OK)) { - - - - // State vector: - // 0-3: quaternions (q0, q1, q2, q3) - // 4-6: Velocity - m/sec (North, East, Down) - // 7-9: Position - m (North, East, Down) - // 10-12: Delta Angle bias - rad (X,Y,Z) - // 13-14: Wind Vector - m/sec (North,East) - // 15-17: Earth Magnetic Field Vector - milligauss (North, East, Down) - // 18-20: Body Magnetic Field Vector - milligauss (X,Y,Z) - - math::Quaternion q(_ekf->states[0], _ekf->states[1], _ekf->states[2], _ekf->states[3]); - math::Matrix<3, 3> R = q.to_dcm(); - math::Vector<3> euler = R.to_euler(); - - for (int i = 0; i < 3; i++) for (int j = 0; j < 3; j++) - _att.R[i][j] = R(i, j); - - _att.timestamp = last_sensor_timestamp; - _att.q[0] = _ekf->states[0]; - _att.q[1] = _ekf->states[1]; - _att.q[2] = _ekf->states[2]; - _att.q[3] = _ekf->states[3]; - _att.q_valid = true; - _att.R_valid = true; - - _att.timestamp = last_sensor_timestamp; - _att.roll = euler(0); - _att.pitch = euler(1); - _att.yaw = euler(2); - - _att.rollspeed = _ekf->angRate.x - _ekf->states[10]; - _att.pitchspeed = _ekf->angRate.y - _ekf->states[11]; - _att.yawspeed = _ekf->angRate.z - _ekf->states[12]; - // gyro offsets - _att.rate_offsets[0] = _ekf->states[10]; - _att.rate_offsets[1] = _ekf->states[11]; - _att.rate_offsets[2] = _ekf->states[12]; - - /* lazily publish the attitude only once available */ - if (_att_pub > 0) { - /* publish the attitude setpoint */ - orb_publish(ORB_ID(vehicle_attitude), _att_pub, &_att); + // Fuse GPS Measurements + if (newDataGps && _gps_initialized) { + // Convert GPS measurements to Pos NE, hgt and Vel NED + + float gps_dt = (_gps.timestamp_position - last_gps) / 1e6f; + + // Calculate acceleration predicted by GPS velocity change + if (((fabsf(_ekf->velNED[0] - _gps.vel_n_m_s) > FLT_EPSILON) || + (fabsf(_ekf->velNED[1] - _gps.vel_e_m_s) > FLT_EPSILON) || + (fabsf(_ekf->velNED[2] - _gps.vel_d_m_s) > FLT_EPSILON)) && (gps_dt > 0.00001f)) { + + _ekf->accelGPSNED[0] = (_ekf->velNED[0] - _gps.vel_n_m_s) / gps_dt; + _ekf->accelGPSNED[1] = (_ekf->velNED[1] - _gps.vel_e_m_s) / gps_dt; + _ekf->accelGPSNED[2] = (_ekf->velNED[2] - _gps.vel_d_m_s) / gps_dt; + } + + _ekf->velNED[0] = _gps.vel_n_m_s; + _ekf->velNED[1] = _gps.vel_e_m_s; + _ekf->velNED[2] = _gps.vel_d_m_s; + _ekf->calcposNED(posNED, _ekf->gpsLat, _ekf->gpsLon, _ekf->gpsHgt, _ekf->latRef, _ekf->lonRef, _ekf->hgtRef); + + _ekf->posNE[0] = posNED[0]; + _ekf->posNE[1] = posNED[1]; + // set fusion flags + _ekf->fuseVelData = true; + _ekf->fusePosData = true; + // recall states stored at time of measurement after adjusting for delays + _ekf->RecallStates(_ekf->statesAtVelTime, (IMUmsec - _parameters.vel_delay_ms)); + _ekf->RecallStates(_ekf->statesAtPosTime, (IMUmsec - _parameters.pos_delay_ms)); + // run the fusion step + _ekf->FuseVelposNED(); + + } else if (_ekf->statesInitialised) { + // Convert GPS measurements to Pos NE, hgt and Vel NED + _ekf->velNED[0] = 0.0f; + _ekf->velNED[1] = 0.0f; + _ekf->velNED[2] = 0.0f; + + _ekf->posNE[0] = 0.0f; + _ekf->posNE[1] = 0.0f; + // set fusion flags + _ekf->fuseVelData = true; + _ekf->fusePosData = true; + // recall states stored at time of measurement after adjusting for delays + _ekf->RecallStates(_ekf->statesAtVelTime, (IMUmsec - _parameters.vel_delay_ms)); + _ekf->RecallStates(_ekf->statesAtPosTime, (IMUmsec - _parameters.pos_delay_ms)); + // run the fusion step + _ekf->FuseVelposNED(); - } else { - /* advertise and publish */ - _att_pub = orb_advertise(ORB_ID(vehicle_attitude), &_att); - } - } + } else { + _ekf->fuseVelData = false; + _ekf->fusePosData = false; + } - if (_gps_initialized) { - _local_pos.timestamp = last_sensor_timestamp; - _local_pos.x = _ekf->states[7]; - _local_pos.y = _ekf->states[8]; - // XXX need to announce change of Z reference somehow elegantly - _local_pos.z = _ekf->states[9] - _baro_gps_offset; - - _local_pos.vx = _ekf->states[4]; - _local_pos.vy = _ekf->states[5]; - _local_pos.vz = _ekf->states[6]; - - _local_pos.xy_valid = _gps_initialized; - _local_pos.z_valid = true; - _local_pos.v_xy_valid = _gps_initialized; - _local_pos.v_z_valid = true; - _local_pos.xy_global = true; - - _local_pos.z_global = false; - _local_pos.yaw = _att.yaw; - - _velocity_xy_filtered = 0.95f*_velocity_xy_filtered + 0.05f*sqrtf(_local_pos.vx*_local_pos.vx + _local_pos.vy*_local_pos.vy); - _velocity_z_filtered = 0.95f*_velocity_z_filtered + 0.05f*fabsf(_local_pos.vz); - _airspeed_filtered = 0.95*_airspeed_filtered + + 0.05*_airspeed.true_airspeed_m_s; - - - /* crude land detector for fixedwing only, - * TODO: adapt so that it works for both, maybe move to another location - */ - if (_velocity_xy_filtered < 5 - && _velocity_z_filtered < 10 - && _airspeed_filtered < 10) { - _local_pos.landed = true; - } else { - _local_pos.landed = false; - } + if (newHgtData && _ekf->statesInitialised) { + // Could use a blend of GPS and baro alt data if desired + _ekf->hgtMea = 1.0f * (_ekf->baroHgt - _baro_ref); + _ekf->fuseHgtData = true; + // recall states stored at time of measurement after adjusting for delays + _ekf->RecallStates(_ekf->statesAtHgtTime, (IMUmsec - _parameters.height_delay_ms)); + // run the fusion step + _ekf->FuseVelposNED(); - /* lazily publish the local position only once available */ - if (_local_pos_pub > 0) { - /* publish the attitude setpoint */ - orb_publish(ORB_ID(vehicle_local_position), _local_pos_pub, &_local_pos); + } else { + _ekf->fuseHgtData = false; + } - } else { - /* advertise and publish */ - _local_pos_pub = orb_advertise(ORB_ID(vehicle_local_position), &_local_pos); - } + // Fuse Magnetometer Measurements + if (newDataMag && _ekf->statesInitialised) { + _ekf->fuseMagData = true; + _ekf->RecallStates(_ekf->statesAtMagMeasTime, (IMUmsec - _parameters.mag_delay_ms)); // Assume 50 msec avg delay for magnetometer data - _global_pos.timestamp = _local_pos.timestamp; + _ekf->magstate.obsIndex = 0; + _ekf->FuseMagnetometer(); + _ekf->FuseMagnetometer(); + _ekf->FuseMagnetometer(); - if (_local_pos.xy_global) { - double est_lat, est_lon; - map_projection_reproject(&_pos_ref, _local_pos.x, _local_pos.y, &est_lat, &est_lon); - _global_pos.lat = est_lat; - _global_pos.lon = est_lon; - _global_pos.time_gps_usec = _gps.time_gps_usec; - _global_pos.eph = _gps.eph; - _global_pos.epv = _gps.epv; - } + } else { + _ekf->fuseMagData = false; + } - if (_local_pos.v_xy_valid) { - _global_pos.vel_n = _local_pos.vx; - _global_pos.vel_e = _local_pos.vy; - } else { - _global_pos.vel_n = 0.0f; - _global_pos.vel_e = 0.0f; - } + // Fuse Airspeed Measurements + if (newAdsData && _ekf->statesInitialised && _ekf->VtasMeas > 8.0f) { + _ekf->fuseVtasData = true; + _ekf->RecallStates(_ekf->statesAtVtasMeasTime, (IMUmsec - _parameters.tas_delay_ms)); // assume 100 msec avg delay for airspeed data + _ekf->FuseAirspeed(); - /* local pos alt is negative, change sign and add alt offsets */ - _global_pos.alt = _local_pos.ref_alt + _baro_gps_offset + (-_local_pos.z); + } else { + _ekf->fuseVtasData = false; + } - if (_local_pos.v_z_valid) { - _global_pos.vel_d = _local_pos.vz; - } - _global_pos.yaw = _local_pos.yaw; + // Output results + math::Quaternion q(_ekf->states[0], _ekf->states[1], _ekf->states[2], _ekf->states[3]); + math::Matrix<3, 3> R = q.to_dcm(); + math::Vector<3> euler = R.to_euler(); + + for (int i = 0; i < 3; i++) for (int j = 0; j < 3; j++) + _att.R[i][j] = R(i, j); + + _att.timestamp = _last_sensor_timestamp; + _att.q[0] = _ekf->states[0]; + _att.q[1] = _ekf->states[1]; + _att.q[2] = _ekf->states[2]; + _att.q[3] = _ekf->states[3]; + _att.q_valid = true; + _att.R_valid = true; + + _att.timestamp = _last_sensor_timestamp; + _att.roll = euler(0); + _att.pitch = euler(1); + _att.yaw = euler(2); + + _att.rollspeed = _ekf->angRate.x - _ekf->states[10]; + _att.pitchspeed = _ekf->angRate.y - _ekf->states[11]; + _att.yawspeed = _ekf->angRate.z - _ekf->states[12]; + // gyro offsets + _att.rate_offsets[0] = _ekf->states[10]; + _att.rate_offsets[1] = _ekf->states[11]; + _att.rate_offsets[2] = _ekf->states[12]; + + /* lazily publish the attitude only once available */ + if (_att_pub > 0) { + /* publish the attitude setpoint */ + orb_publish(ORB_ID(vehicle_attitude), _att_pub, &_att); - _global_pos.eph = _gps.eph; - _global_pos.epv = _gps.epv; + } else { + /* advertise and publish */ + _att_pub = orb_advertise(ORB_ID(vehicle_attitude), &_att); + } - _global_pos.timestamp = _local_pos.timestamp; + if (_gps_initialized) { + _local_pos.timestamp = _last_sensor_timestamp; + _local_pos.x = _ekf->states[7]; + _local_pos.y = _ekf->states[8]; + // XXX need to announce change of Z reference somehow elegantly + _local_pos.z = _ekf->states[9] - _baro_ref_offset; + + _local_pos.vx = _ekf->states[4]; + _local_pos.vy = _ekf->states[5]; + _local_pos.vz = _ekf->states[6]; + + _local_pos.xy_valid = _gps_initialized; + _local_pos.z_valid = true; + _local_pos.v_xy_valid = _gps_initialized; + _local_pos.v_z_valid = true; + _local_pos.xy_global = true; + + _velocity_xy_filtered = 0.95f*_velocity_xy_filtered + 0.05f*sqrtf(_local_pos.vx*_local_pos.vx + _local_pos.vy*_local_pos.vy); + _velocity_z_filtered = 0.95f*_velocity_z_filtered + 0.05f*fabsf(_local_pos.vz); + _airspeed_filtered = 0.95f*_airspeed_filtered + + 0.05f*_airspeed.true_airspeed_m_s; + + + /* crude land detector for fixedwing only, + * TODO: adapt so that it works for both, maybe move to another location + */ + if (_velocity_xy_filtered < 5 + && _velocity_z_filtered < 10 + && _airspeed_filtered < 10) { + _local_pos.landed = true; + } else { + _local_pos.landed = false; + } + + _local_pos.z_global = false; + _local_pos.yaw = _att.yaw; + + /* lazily publish the local position only once available */ + if (_local_pos_pub > 0) { + /* publish the attitude setpoint */ + orb_publish(ORB_ID(vehicle_local_position), _local_pos_pub, &_local_pos); + + } else { + /* advertise and publish */ + _local_pos_pub = orb_advertise(ORB_ID(vehicle_local_position), &_local_pos); + } + + _global_pos.timestamp = _local_pos.timestamp; + + if (_local_pos.xy_global) { + double est_lat, est_lon; + map_projection_reproject(&_pos_ref, _local_pos.x, _local_pos.y, &est_lat, &est_lon); + _global_pos.lat = est_lat; + _global_pos.lon = est_lon; + _global_pos.time_gps_usec = _gps.time_gps_usec; + _global_pos.eph = _gps.eph; + _global_pos.epv = _gps.epv; + } + + if (_local_pos.v_xy_valid) { + _global_pos.vel_n = _local_pos.vx; + _global_pos.vel_e = _local_pos.vy; + } else { + _global_pos.vel_n = 0.0f; + _global_pos.vel_e = 0.0f; + } + + /* local pos alt is negative, change sign and add alt offsets */ + _global_pos.alt = _baro_ref + (-_local_pos.z) - _baro_gps_offset; + + if (_local_pos.v_z_valid) { + _global_pos.vel_d = _local_pos.vz; + } + + + _global_pos.yaw = _local_pos.yaw; + + _global_pos.eph = _gps.eph; + _global_pos.epv = _gps.epv; + + _global_pos.timestamp = _local_pos.timestamp; + + /* lazily publish the global position only once available */ + if (_global_pos_pub > 0) { + /* publish the global position */ + orb_publish(ORB_ID(vehicle_global_position), _global_pos_pub, &_global_pos); + + } else { + /* advertise and publish */ + _global_pos_pub = orb_advertise(ORB_ID(vehicle_global_position), &_global_pos); + } + + if (hrt_elapsed_time(&_wind.timestamp) > 99000) { + _wind.timestamp = _global_pos.timestamp; + _wind.windspeed_north = _ekf->states[14]; + _wind.windspeed_east = _ekf->states[15]; + _wind.covariance_north = 0.0f; // XXX get form filter + _wind.covariance_east = 0.0f; + + /* lazily publish the wind estimate only once available */ + if (_wind_pub > 0) { + /* publish the wind estimate */ + orb_publish(ORB_ID(wind_estimate), _wind_pub, &_wind); + + } else { + /* advertise and publish */ + _wind_pub = orb_advertise(ORB_ID(wind_estimate), &_wind); + } + + } - /* lazily publish the global position only once available */ - if (_global_pos_pub > 0) { - /* publish the global position */ - orb_publish(ORB_ID(vehicle_global_position), _global_pos_pub, &_global_pos); + } - } else { - /* advertise and publish */ - _global_pos_pub = orb_advertise(ORB_ID(vehicle_global_position), &_global_pos); } if (hrt_elapsed_time(&_wind.timestamp) > 99000) { @@ -1430,34 +1560,44 @@ FixedwingEstimator::print_status() // 4-6: Velocity - m/sec (North, East, Down) // 7-9: Position - m (North, East, Down) // 10-12: Delta Angle bias - rad (X,Y,Z) - // 13-14: Wind Vector - m/sec (North,East) - // 15-17: Earth Magnetic Field Vector - gauss (North, East, Down) - // 18-20: Body Magnetic Field Vector - gauss (X,Y,Z) + // 13: Accelerometer offset + // 14-15: Wind Vector - m/sec (North,East) + // 16-18: Earth Magnetic Field Vector - gauss (North, East, Down) + // 19-21: Body Magnetic Field Vector - gauss (X,Y,Z) printf("dtIMU: %8.6f IMUmsec: %d\n", (double)_ekf->dtIMU, (int)IMUmsec); - printf("ref alt: %8.6f\n", (double)_local_pos.ref_alt); + printf("baro alt: %8.4f GPS alt: %8.4f\n", (double)_baro.altitude, (double)(_gps.alt / 1e3f)); + printf("ref alt: %8.4f baro ref offset: %8.4f baro GPS offset: %8.4f\n", (double)_baro_ref, (double)_baro_ref_offset, (double)_baro_gps_offset); printf("dvel: %8.6f %8.6f %8.6f accel: %8.6f %8.6f %8.6f\n", (double)_ekf->dVelIMU.x, (double)_ekf->dVelIMU.y, (double)_ekf->dVelIMU.z, (double)_ekf->accel.x, (double)_ekf->accel.y, (double)_ekf->accel.z); printf("dang: %8.4f %8.4f %8.4f dang corr: %8.4f %8.4f %8.4f\n" , (double)_ekf->dAngIMU.x, (double)_ekf->dAngIMU.y, (double)_ekf->dAngIMU.z, (double)_ekf->correctedDelAng.x, (double)_ekf->correctedDelAng.y, (double)_ekf->correctedDelAng.z); - printf("states (quat) [1-4]: %8.4f, %8.4f, %8.4f, %8.4f\n", (double)_ekf->states[0], (double)_ekf->states[1], (double)_ekf->states[2], (double)_ekf->states[3]); - printf("states (vel m/s) [5-7]: %8.4f, %8.4f, %8.4f\n", (double)_ekf->states[4], (double)_ekf->states[5], (double)_ekf->states[6]); - printf("states (pos m) [8-10]: %8.4f, %8.4f, %8.4f\n", (double)_ekf->states[7], (double)_ekf->states[8], (double)_ekf->states[9]); - printf("states (delta ang) [11-13]: %8.4f, %8.4f, %8.4f\n", (double)_ekf->states[10], (double)_ekf->states[11], (double)_ekf->states[12]); - printf("states (accel offs) [14]: %8.4f\n", (double)_ekf->states[13]); - printf("states (wind) [15-16]: %8.4f, %8.4f\n", (double)_ekf->states[14], (double)_ekf->states[15]); - printf("states (earth mag) [17-19]: %8.4f, %8.4f, %8.4f\n", (double)_ekf->states[16], (double)_ekf->states[17], (double)_ekf->states[18]); - printf("states (body mag) [20-22]: %8.4f, %8.4f, %8.4f\n", (double)_ekf->states[19], (double)_ekf->states[20], (double)_ekf->states[21]); - printf("states (terrain) [23]: %8.4f\n", (double)_ekf->states[22]); + printf("states (quat) [0-3]: %8.4f, %8.4f, %8.4f, %8.4f\n", (double)_ekf->states[0], (double)_ekf->states[1], (double)_ekf->states[2], (double)_ekf->states[3]); + printf("states (vel m/s) [4-6]: %8.4f, %8.4f, %8.4f\n", (double)_ekf->states[4], (double)_ekf->states[5], (double)_ekf->states[6]); + printf("states (pos m) [7-9]: %8.4f, %8.4f, %8.4f\n", (double)_ekf->states[7], (double)_ekf->states[8], (double)_ekf->states[9]); + printf("states (delta ang) [10-12]: %8.4f, %8.4f, %8.4f\n", (double)_ekf->states[10], (double)_ekf->states[11], (double)_ekf->states[12]); + + if (n_states == 23) { + printf("states (accel offs) [13]: %8.4f\n", (double)_ekf->states[13]); + printf("states (wind) [14-15]: %8.4f, %8.4f\n", (double)_ekf->states[14], (double)_ekf->states[15]); + printf("states (earth mag) [16-18]: %8.4f, %8.4f, %8.4f\n", (double)_ekf->states[16], (double)_ekf->states[17], (double)_ekf->states[18]); + printf("states (body mag) [19-21]: %8.4f, %8.4f, %8.4f\n", (double)_ekf->states[19], (double)_ekf->states[20], (double)_ekf->states[21]); + printf("states (terrain) [22]: %8.4f\n", (double)_ekf->states[22]); + + } else { + printf("states (wind) [13-14]: %8.4f, %8.4f\n", (double)_ekf->states[13], (double)_ekf->states[14]); + printf("states (earth mag) [15-17]: %8.4f, %8.4f, %8.4f\n", (double)_ekf->states[15], (double)_ekf->states[16], (double)_ekf->states[17]); + printf("states (body mag) [18-20]: %8.4f, %8.4f, %8.4f\n", (double)_ekf->states[18], (double)_ekf->states[19], (double)_ekf->states[20]); + } printf("states: %s %s %s %s %s %s %s %s %s %s\n", - (_ekf->statesInitialised) ? "INITIALIZED" : "NON_INIT", - (_ekf->onGround) ? "ON_GROUND" : "AIRBORNE", - (_ekf->fuseVelData) ? "FUSE_VEL" : "INH_VEL", - (_ekf->fusePosData) ? "FUSE_POS" : "INH_POS", - (_ekf->fuseHgtData) ? "FUSE_HGT" : "INH_HGT", - (_ekf->fuseMagData) ? "FUSE_MAG" : "INH_MAG", - (_ekf->fuseVtasData) ? "FUSE_VTAS" : "INH_VTAS", - (_ekf->useAirspeed) ? "USE_AIRSPD" : "IGN_AIRSPD", - (_ekf->useCompass) ? "USE_COMPASS" : "IGN_COMPASS", - (_ekf->staticMode) ? "STATIC_MODE" : "DYNAMIC_MODE"); + (_ekf->statesInitialised) ? "INITIALIZED" : "NON_INIT", + (_ekf->onGround) ? "ON_GROUND" : "AIRBORNE", + (_ekf->fuseVelData) ? "FUSE_VEL" : "INH_VEL", + (_ekf->fusePosData) ? "FUSE_POS" : "INH_POS", + (_ekf->fuseHgtData) ? "FUSE_HGT" : "INH_HGT", + (_ekf->fuseMagData) ? "FUSE_MAG" : "INH_MAG", + (_ekf->fuseVtasData) ? "FUSE_VTAS" : "INH_VTAS", + (_ekf->useAirspeed) ? "USE_AIRSPD" : "IGN_AIRSPD", + (_ekf->useCompass) ? "USE_COMPASS" : "IGN_COMPASS", + (_ekf->staticMode) ? "STATIC_MODE" : "DYNAMIC_MODE"); } int FixedwingEstimator::trip_nan() { @@ -1512,7 +1652,7 @@ int FixedwingEstimator::trip_nan() { int ekf_att_pos_estimator_main(int argc, char *argv[]) { if (argc < 1) - errx(1, "usage: ekf_att_pos_estimator {start|stop|status}"); + errx(1, "usage: ekf_att_pos_estimator {start|stop|status|logging}"); if (!strcmp(argv[1], "start")) { @@ -1566,6 +1706,29 @@ int ekf_att_pos_estimator_main(int argc, char *argv[]) } } + if (!strcmp(argv[1], "logging")) { + if (estimator::g_estimator) { + int ret = estimator::g_estimator->enable_logging(true); + + exit(ret); + + } else { + errx(1, "not running"); + } + } + + if (!strcmp(argv[1], "debug")) { + if (estimator::g_estimator) { + int debug = strtoul(argv[2], NULL, 10); + int ret = estimator::g_estimator->set_debuglevel(debug); + + exit(ret); + + } else { + errx(1, "not running"); + } + } + warnx("unrecognized command"); return 1; } diff --git a/src/modules/ekf_att_pos_estimator/estimator_21states.cpp b/src/modules/ekf_att_pos_estimator/estimator_21states.cpp new file mode 100644 index 000000000..67bfec4ea --- /dev/null +++ b/src/modules/ekf_att_pos_estimator/estimator_21states.cpp @@ -0,0 +1,2142 @@ +#include "estimator_21states.h" + +#include <string.h> + +AttPosEKF::AttPosEKF() : + fusionModeGPS(0), + covSkipCount(0), + EAS2TAS(1.0f), + statesInitialised(false), + fuseVelData(false), + fusePosData(false), + fuseHgtData(false), + fuseMagData(false), + fuseVtasData(false), + onGround(true), + staticMode(true), + useAirspeed(true), + useCompass(true), + numericalProtection(true), + storeIndex(0), + magDeclination(0.0f) +{ + InitialiseParameters(); +} + +AttPosEKF::~AttPosEKF() +{ +} + +void AttPosEKF::UpdateStrapdownEquationsNED() +{ + Vector3f delVelNav; + float q00; + float q11; + float q22; + float q33; + float q01; + float q02; + float q03; + float q12; + float q13; + float q23; + Mat3f Tbn; + Mat3f Tnb; + float rotationMag; + float qUpdated[4]; + float quatMag; + double deltaQuat[4]; + const Vector3f gravityNED = {0.0,0.0,GRAVITY_MSS}; + +// Remove sensor bias errors + correctedDelAng.x = dAngIMU.x - states[10]; + correctedDelAng.y = dAngIMU.y - states[11]; + correctedDelAng.z = dAngIMU.z - states[12]; + dVelIMU.x = dVelIMU.x; + dVelIMU.y = dVelIMU.y; + dVelIMU.z = dVelIMU.z; + +// Save current measurements + Vector3f prevDelAng = correctedDelAng; + +// Apply corrections for earths rotation rate and coning errors +// * and + operators have been overloaded + correctedDelAng = correctedDelAng - Tnb*earthRateNED*dtIMU + 8.333333333333333e-2f*(prevDelAng % correctedDelAng); +// Convert the rotation vector to its equivalent quaternion + rotationMag = correctedDelAng.length(); + if (rotationMag < 1e-12f) + { + deltaQuat[0] = 1.0; + deltaQuat[1] = 0.0; + deltaQuat[2] = 0.0; + deltaQuat[3] = 0.0; + } + else + { + deltaQuat[0] = cos(0.5f*rotationMag); + double rotScaler = (sin(0.5f*rotationMag))/rotationMag; + deltaQuat[1] = correctedDelAng.x*rotScaler; + deltaQuat[2] = correctedDelAng.y*rotScaler; + deltaQuat[3] = correctedDelAng.z*rotScaler; + } + +// Update the quaternions by rotating from the previous attitude through +// the delta angle rotation quaternion + qUpdated[0] = states[0]*deltaQuat[0] - states[1]*deltaQuat[1] - states[2]*deltaQuat[2] - states[3]*deltaQuat[3]; + qUpdated[1] = states[0]*deltaQuat[1] + states[1]*deltaQuat[0] + states[2]*deltaQuat[3] - states[3]*deltaQuat[2]; + qUpdated[2] = states[0]*deltaQuat[2] + states[2]*deltaQuat[0] + states[3]*deltaQuat[1] - states[1]*deltaQuat[3]; + qUpdated[3] = states[0]*deltaQuat[3] + states[3]*deltaQuat[0] + states[1]*deltaQuat[2] - states[2]*deltaQuat[1]; + +// Normalise the quaternions and update the quaternion states + quatMag = sqrtf(sq(qUpdated[0]) + sq(qUpdated[1]) + sq(qUpdated[2]) + sq(qUpdated[3])); + if (quatMag > 1e-16f) + { + float quatMagInv = 1.0f/quatMag; + states[0] = quatMagInv*qUpdated[0]; + states[1] = quatMagInv*qUpdated[1]; + states[2] = quatMagInv*qUpdated[2]; + states[3] = quatMagInv*qUpdated[3]; + } + +// Calculate the body to nav cosine matrix + q00 = sq(states[0]); + q11 = sq(states[1]); + q22 = sq(states[2]); + q33 = sq(states[3]); + q01 = states[0]*states[1]; + q02 = states[0]*states[2]; + q03 = states[0]*states[3]; + q12 = states[1]*states[2]; + q13 = states[1]*states[3]; + q23 = states[2]*states[3]; + + Tbn.x.x = q00 + q11 - q22 - q33; + Tbn.y.y = q00 - q11 + q22 - q33; + Tbn.z.z = q00 - q11 - q22 + q33; + Tbn.x.y = 2*(q12 - q03); + Tbn.x.z = 2*(q13 + q02); + Tbn.y.x = 2*(q12 + q03); + Tbn.y.z = 2*(q23 - q01); + Tbn.z.x = 2*(q13 - q02); + Tbn.z.y = 2*(q23 + q01); + + Tnb = Tbn.transpose(); + +// transform body delta velocities to delta velocities in the nav frame +// * and + operators have been overloaded + //delVelNav = Tbn*dVelIMU + gravityNED*dtIMU; + delVelNav.x = Tbn.x.x*dVelIMU.x + Tbn.x.y*dVelIMU.y + Tbn.x.z*dVelIMU.z + gravityNED.x*dtIMU; + delVelNav.y = Tbn.y.x*dVelIMU.x + Tbn.y.y*dVelIMU.y + Tbn.y.z*dVelIMU.z + gravityNED.y*dtIMU; + delVelNav.z = Tbn.z.x*dVelIMU.x + Tbn.z.y*dVelIMU.y + Tbn.z.z*dVelIMU.z + gravityNED.z*dtIMU; + +// calculate the magnitude of the nav acceleration (required for GPS +// variance estimation) + accNavMag = delVelNav.length()/dtIMU; + +// If calculating position save previous velocity + float lastVelocity[3]; + lastVelocity[0] = states[4]; + lastVelocity[1] = states[5]; + lastVelocity[2] = states[6]; + +// Sum delta velocities to get velocity + states[4] = states[4] + delVelNav.x; + states[5] = states[5] + delVelNav.y; + states[6] = states[6] + delVelNav.z; + +// If calculating postions, do a trapezoidal integration for position + states[7] = states[7] + 0.5f*(states[4] + lastVelocity[0])*dtIMU; + states[8] = states[8] + 0.5f*(states[5] + lastVelocity[1])*dtIMU; + states[9] = states[9] + 0.5f*(states[6] + lastVelocity[2])*dtIMU; + + // Constrain states (to protect against filter divergence) + //ConstrainStates(); +} + +void AttPosEKF::CovariancePrediction(float dt) +{ + // scalars + float daxCov; + float dayCov; + float dazCov; + float dvxCov; + float dvyCov; + float dvzCov; + float dvx; + float dvy; + float dvz; + float dax; + float day; + float daz; + float q0; + float q1; + float q2; + float q3; + float dax_b; + float day_b; + float daz_b; + + // arrays + float processNoise[21]; + float SF[14]; + float SG[8]; + float SQ[11]; + float SPP[13] = {0}; + float nextP[21][21]; + + // calculate covariance prediction process noise + windVelSigma = dt*0.1f; + dAngBiasSigma = dt*5.0e-7f; + magEarthSigma = dt*3.0e-4f; + magBodySigma = dt*3.0e-4f; + for (uint8_t i= 0; i<=9; i++) processNoise[i] = 1.0e-9f; + for (uint8_t i=10; i<=12; i++) processNoise[i] = dAngBiasSigma; + if (onGround) processNoise[12] = dAngBiasSigma * yawVarScale; + for (uint8_t i=13; i<=14; i++) processNoise[i] = windVelSigma; + for (uint8_t i=15; i<=17; i++) processNoise[i] = magEarthSigma; + for (uint8_t i=18; i<=20; i++) processNoise[i] = magBodySigma; + for (uint8_t i= 0; i<=20; i++) processNoise[i] = sq(processNoise[i]); + + // set variables used to calculate covariance growth + dvx = summedDelVel.x; + dvy = summedDelVel.y; + dvz = summedDelVel.z; + dax = summedDelAng.x; + day = summedDelAng.y; + daz = summedDelAng.z; + q0 = states[0]; + q1 = states[1]; + q2 = states[2]; + q3 = states[3]; + dax_b = states[10]; + day_b = states[11]; + daz_b = states[12]; + daxCov = sq(dt*1.4544411e-2f); + dayCov = sq(dt*1.4544411e-2f); + dazCov = sq(dt*1.4544411e-2f); + if (onGround) dazCov = dazCov * sq(yawVarScale); + dvxCov = sq(dt*0.5f); + dvyCov = sq(dt*0.5f); + dvzCov = sq(dt*0.5f); + + // Predicted covariance calculation + SF[0] = 2*dvx*q1 + 2*dvy*q2 + 2*dvz*q3; + SF[1] = 2*dvx*q3 + 2*dvy*q0 - 2*dvz*q1; + SF[2] = 2*dvx*q0 - 2*dvy*q3 + 2*dvz*q2; + SF[3] = day/2 - day_b/2; + SF[4] = daz/2 - daz_b/2; + SF[5] = dax/2 - dax_b/2; + SF[6] = dax_b/2 - dax/2; + SF[7] = daz_b/2 - daz/2; + SF[8] = day_b/2 - day/2; + SF[9] = q1/2; + SF[10] = q2/2; + SF[11] = q3/2; + SF[12] = 2*dvz*q0; + SF[13] = 2*dvy*q1; + + SG[0] = q0/2; + SG[1] = sq(q3); + SG[2] = sq(q2); + SG[3] = sq(q1); + SG[4] = sq(q0); + SG[5] = 2*q2*q3; + SG[6] = 2*q1*q3; + SG[7] = 2*q1*q2; + + SQ[0] = dvzCov*(SG[5] - 2*q0*q1)*(SG[1] - SG[2] - SG[3] + SG[4]) - dvyCov*(SG[5] + 2*q0*q1)*(SG[1] - SG[2] + SG[3] - SG[4]) + dvxCov*(SG[6] - 2*q0*q2)*(SG[7] + 2*q0*q3); + SQ[1] = dvzCov*(SG[6] + 2*q0*q2)*(SG[1] - SG[2] - SG[3] + SG[4]) - dvxCov*(SG[6] - 2*q0*q2)*(SG[1] + SG[2] - SG[3] - SG[4]) + dvyCov*(SG[5] + 2*q0*q1)*(SG[7] - 2*q0*q3); + SQ[2] = dvzCov*(SG[5] - 2*q0*q1)*(SG[6] + 2*q0*q2) - dvyCov*(SG[7] - 2*q0*q3)*(SG[1] - SG[2] + SG[3] - SG[4]) - dvxCov*(SG[7] + 2*q0*q3)*(SG[1] + SG[2] - SG[3] - SG[4]); + SQ[3] = (dayCov*q1*SG[0])/2 - (dazCov*q1*SG[0])/2 - (daxCov*q2*q3)/4; + SQ[4] = (dazCov*q2*SG[0])/2 - (daxCov*q2*SG[0])/2 - (dayCov*q1*q3)/4; + SQ[5] = (daxCov*q3*SG[0])/2 - (dayCov*q3*SG[0])/2 - (dazCov*q1*q2)/4; + SQ[6] = (daxCov*q1*q2)/4 - (dazCov*q3*SG[0])/2 - (dayCov*q1*q2)/4; + SQ[7] = (dazCov*q1*q3)/4 - (daxCov*q1*q3)/4 - (dayCov*q2*SG[0])/2; + SQ[8] = (dayCov*q2*q3)/4 - (daxCov*q1*SG[0])/2 - (dazCov*q2*q3)/4; + SQ[9] = sq(SG[0]); + SQ[10] = sq(q1); + + SPP[0] = SF[12] + SF[13] - 2*dvx*q2; + SPP[1] = 2*dvx*q0 - 2*dvy*q3 + 2*dvz*q2; + SPP[2] = 2*dvx*q3 + 2*dvy*q0 - 2*dvz*q1; + SPP[3] = SF[11]; + SPP[4] = SF[10]; + SPP[5] = SF[9]; + SPP[6] = SF[7]; + SPP[7] = SF[8]; + + nextP[0][0] = P[0][0] + P[1][0]*SF[6] + P[2][0]*SPP[7] + P[3][0]*SPP[6] + P[10][0]*SPP[5] + P[11][0]*SPP[4] + P[12][0]*SPP[3] + (daxCov*SQ[10])/4 + SF[6]*(P[0][1] + P[1][1]*SF[6] + P[2][1]*SPP[7] + P[3][1]*SPP[6] + P[10][1]*SPP[5] + P[11][1]*SPP[4] + P[12][1]*SPP[3]) + SPP[7]*(P[0][2] + P[1][2]*SF[6] + P[2][2]*SPP[7] + P[3][2]*SPP[6] + P[10][2]*SPP[5] + P[11][2]*SPP[4] + P[12][2]*SPP[3]) + SPP[6]*(P[0][3] + P[1][3]*SF[6] + P[2][3]*SPP[7] + P[3][3]*SPP[6] + P[10][3]*SPP[5] + P[11][3]*SPP[4] + P[12][3]*SPP[3]) + SPP[5]*(P[0][10] + P[1][10]*SF[6] + P[2][10]*SPP[7] + P[3][10]*SPP[6] + P[10][10]*SPP[5] + P[11][10]*SPP[4] + P[12][10]*SPP[3]) + SPP[4]*(P[0][11] + P[1][11]*SF[6] + P[2][11]*SPP[7] + P[3][11]*SPP[6] + P[10][11]*SPP[5] + P[11][11]*SPP[4] + P[12][11]*SPP[3]) + SPP[3]*(P[0][12] + P[1][12]*SF[6] + P[2][12]*SPP[7] + P[3][12]*SPP[6] + P[10][12]*SPP[5] + P[11][12]*SPP[4] + P[12][12]*SPP[3]) + (dayCov*sq(q2))/4 + (dazCov*sq(q3))/4; + nextP[0][1] = P[0][1] + SQ[8] + P[1][1]*SF[6] + P[2][1]*SPP[7] + P[3][1]*SPP[6] + P[10][1]*SPP[5] + P[11][1]*SPP[4] + P[12][1]*SPP[3] + SF[5]*(P[0][0] + P[1][0]*SF[6] + P[2][0]*SPP[7] + P[3][0]*SPP[6] + P[10][0]*SPP[5] + P[11][0]*SPP[4] + P[12][0]*SPP[3]) + SF[4]*(P[0][2] + P[1][2]*SF[6] + P[2][2]*SPP[7] + P[3][2]*SPP[6] + P[10][2]*SPP[5] + P[11][2]*SPP[4] + P[12][2]*SPP[3]) + SPP[7]*(P[0][3] + P[1][3]*SF[6] + P[2][3]*SPP[7] + P[3][3]*SPP[6] + P[10][3]*SPP[5] + P[11][3]*SPP[4] + P[12][3]*SPP[3]) + SPP[3]*(P[0][11] + P[1][11]*SF[6] + P[2][11]*SPP[7] + P[3][11]*SPP[6] + P[10][11]*SPP[5] + P[11][11]*SPP[4] + P[12][11]*SPP[3]) - SPP[4]*(P[0][12] + P[1][12]*SF[6] + P[2][12]*SPP[7] + P[3][12]*SPP[6] + P[10][12]*SPP[5] + P[11][12]*SPP[4] + P[12][12]*SPP[3]) - (q0*(P[0][10] + P[1][10]*SF[6] + P[2][10]*SPP[7] + P[3][10]*SPP[6] + P[10][10]*SPP[5] + P[11][10]*SPP[4] + P[12][10]*SPP[3]))/2; + nextP[0][2] = P[0][2] + SQ[7] + P[1][2]*SF[6] + P[2][2]*SPP[7] + P[3][2]*SPP[6] + P[10][2]*SPP[5] + P[11][2]*SPP[4] + P[12][2]*SPP[3] + SF[3]*(P[0][0] + P[1][0]*SF[6] + P[2][0]*SPP[7] + P[3][0]*SPP[6] + P[10][0]*SPP[5] + P[11][0]*SPP[4] + P[12][0]*SPP[3]) + SF[5]*(P[0][3] + P[1][3]*SF[6] + P[2][3]*SPP[7] + P[3][3]*SPP[6] + P[10][3]*SPP[5] + P[11][3]*SPP[4] + P[12][3]*SPP[3]) + SPP[6]*(P[0][1] + P[1][1]*SF[6] + P[2][1]*SPP[7] + P[3][1]*SPP[6] + P[10][1]*SPP[5] + P[11][1]*SPP[4] + P[12][1]*SPP[3]) - SPP[3]*(P[0][10] + P[1][10]*SF[6] + P[2][10]*SPP[7] + P[3][10]*SPP[6] + P[10][10]*SPP[5] + P[11][10]*SPP[4] + P[12][10]*SPP[3]) + SPP[5]*(P[0][12] + P[1][12]*SF[6] + P[2][12]*SPP[7] + P[3][12]*SPP[6] + P[10][12]*SPP[5] + P[11][12]*SPP[4] + P[12][12]*SPP[3]) - (q0*(P[0][11] + P[1][11]*SF[6] + P[2][11]*SPP[7] + P[3][11]*SPP[6] + P[10][11]*SPP[5] + P[11][11]*SPP[4] + P[12][11]*SPP[3]))/2; + nextP[0][3] = P[0][3] + SQ[6] + P[1][3]*SF[6] + P[2][3]*SPP[7] + P[3][3]*SPP[6] + P[10][3]*SPP[5] + P[11][3]*SPP[4] + P[12][3]*SPP[3] + SF[4]*(P[0][0] + P[1][0]*SF[6] + P[2][0]*SPP[7] + P[3][0]*SPP[6] + P[10][0]*SPP[5] + P[11][0]*SPP[4] + P[12][0]*SPP[3]) + SF[3]*(P[0][1] + P[1][1]*SF[6] + P[2][1]*SPP[7] + P[3][1]*SPP[6] + P[10][1]*SPP[5] + P[11][1]*SPP[4] + P[12][1]*SPP[3]) + SF[6]*(P[0][2] + P[1][2]*SF[6] + P[2][2]*SPP[7] + P[3][2]*SPP[6] + P[10][2]*SPP[5] + P[11][2]*SPP[4] + P[12][2]*SPP[3]) + SPP[4]*(P[0][10] + P[1][10]*SF[6] + P[2][10]*SPP[7] + P[3][10]*SPP[6] + P[10][10]*SPP[5] + P[11][10]*SPP[4] + P[12][10]*SPP[3]) - SPP[5]*(P[0][11] + P[1][11]*SF[6] + P[2][11]*SPP[7] + P[3][11]*SPP[6] + P[10][11]*SPP[5] + P[11][11]*SPP[4] + P[12][11]*SPP[3]) - (q0*(P[0][12] + P[1][12]*SF[6] + P[2][12]*SPP[7] + P[3][12]*SPP[6] + P[10][12]*SPP[5] + P[11][12]*SPP[4] + P[12][12]*SPP[3]))/2; + nextP[0][4] = P[0][4] + P[1][4]*SF[6] + P[2][4]*SPP[7] + P[3][4]*SPP[6] + P[10][4]*SPP[5] + P[11][4]*SPP[4] + P[12][4]*SPP[3] + SF[2]*(P[0][0] + P[1][0]*SF[6] + P[2][0]*SPP[7] + P[3][0]*SPP[6] + P[10][0]*SPP[5] + P[11][0]*SPP[4] + P[12][0]*SPP[3]) + SF[0]*(P[0][1] + P[1][1]*SF[6] + P[2][1]*SPP[7] + P[3][1]*SPP[6] + P[10][1]*SPP[5] + P[11][1]*SPP[4] + P[12][1]*SPP[3]) + SPP[0]*(P[0][2] + P[1][2]*SF[6] + P[2][2]*SPP[7] + P[3][2]*SPP[6] + P[10][2]*SPP[5] + P[11][2]*SPP[4] + P[12][2]*SPP[3]) - SPP[2]*(P[0][3] + P[1][3]*SF[6] + P[2][3]*SPP[7] + P[3][3]*SPP[6] + P[10][3]*SPP[5] + P[11][3]*SPP[4] + P[12][3]*SPP[3]); + nextP[0][5] = P[0][5] + P[1][5]*SF[6] + P[2][5]*SPP[7] + P[3][5]*SPP[6] + P[10][5]*SPP[5] + P[11][5]*SPP[4] + P[12][5]*SPP[3] + SF[1]*(P[0][0] + P[1][0]*SF[6] + P[2][0]*SPP[7] + P[3][0]*SPP[6] + P[10][0]*SPP[5] + P[11][0]*SPP[4] + P[12][0]*SPP[3]) + SF[0]*(P[0][2] + P[1][2]*SF[6] + P[2][2]*SPP[7] + P[3][2]*SPP[6] + P[10][2]*SPP[5] + P[11][2]*SPP[4] + P[12][2]*SPP[3]) + SF[2]*(P[0][3] + P[1][3]*SF[6] + P[2][3]*SPP[7] + P[3][3]*SPP[6] + P[10][3]*SPP[5] + P[11][3]*SPP[4] + P[12][3]*SPP[3]) - SPP[0]*(P[0][1] + P[1][1]*SF[6] + P[2][1]*SPP[7] + P[3][1]*SPP[6] + P[10][1]*SPP[5] + P[11][1]*SPP[4] + P[12][1]*SPP[3]); + nextP[0][6] = P[0][6] + P[1][6]*SF[6] + P[2][6]*SPP[7] + P[3][6]*SPP[6] + P[10][6]*SPP[5] + P[11][6]*SPP[4] + P[12][6]*SPP[3] + SF[1]*(P[0][1] + P[1][1]*SF[6] + P[2][1]*SPP[7] + P[3][1]*SPP[6] + P[10][1]*SPP[5] + P[11][1]*SPP[4] + P[12][1]*SPP[3]) + SF[0]*(P[0][3] + P[1][3]*SF[6] + P[2][3]*SPP[7] + P[3][3]*SPP[6] + P[10][3]*SPP[5] + P[11][3]*SPP[4] + P[12][3]*SPP[3]) + SPP[0]*(P[0][0] + P[1][0]*SF[6] + P[2][0]*SPP[7] + P[3][0]*SPP[6] + P[10][0]*SPP[5] + P[11][0]*SPP[4] + P[12][0]*SPP[3]) - SPP[1]*(P[0][2] + P[1][2]*SF[6] + P[2][2]*SPP[7] + P[3][2]*SPP[6] + P[10][2]*SPP[5] + P[11][2]*SPP[4] + P[12][2]*SPP[3]); + nextP[0][7] = P[0][7] + P[1][7]*SF[6] + P[2][7]*SPP[7] + P[3][7]*SPP[6] + P[10][7]*SPP[5] + P[11][7]*SPP[4] + P[12][7]*SPP[3] + dt*(P[0][4] + P[1][4]*SF[6] + P[2][4]*SPP[7] + P[3][4]*SPP[6] + P[10][4]*SPP[5] + P[11][4]*SPP[4] + P[12][4]*SPP[3]); + nextP[0][8] = P[0][8] + P[1][8]*SF[6] + P[2][8]*SPP[7] + P[3][8]*SPP[6] + P[10][8]*SPP[5] + P[11][8]*SPP[4] + P[12][8]*SPP[3] + dt*(P[0][5] + P[1][5]*SF[6] + P[2][5]*SPP[7] + P[3][5]*SPP[6] + P[10][5]*SPP[5] + P[11][5]*SPP[4] + P[12][5]*SPP[3]); + nextP[0][9] = P[0][9] + P[1][9]*SF[6] + P[2][9]*SPP[7] + P[3][9]*SPP[6] + P[10][9]*SPP[5] + P[11][9]*SPP[4] + P[12][9]*SPP[3] + dt*(P[0][6] + P[1][6]*SF[6] + P[2][6]*SPP[7] + P[3][6]*SPP[6] + P[10][6]*SPP[5] + P[11][6]*SPP[4] + P[12][6]*SPP[3]); + nextP[0][10] = P[0][10] + P[1][10]*SF[6] + P[2][10]*SPP[7] + P[3][10]*SPP[6] + P[10][10]*SPP[5] + P[11][10]*SPP[4] + P[12][10]*SPP[3]; + nextP[0][11] = P[0][11] + P[1][11]*SF[6] + P[2][11]*SPP[7] + P[3][11]*SPP[6] + P[10][11]*SPP[5] + P[11][11]*SPP[4] + P[12][11]*SPP[3]; + nextP[0][12] = P[0][12] + P[1][12]*SF[6] + P[2][12]*SPP[7] + P[3][12]*SPP[6] + P[10][12]*SPP[5] + P[11][12]*SPP[4] + P[12][12]*SPP[3]; + nextP[0][13] = P[0][13] + P[1][13]*SF[6] + P[2][13]*SPP[7] + P[3][13]*SPP[6] + P[10][13]*SPP[5] + P[11][13]*SPP[4] + P[12][13]*SPP[3]; + nextP[0][14] = P[0][14] + P[1][14]*SF[6] + P[2][14]*SPP[7] + P[3][14]*SPP[6] + P[10][14]*SPP[5] + P[11][14]*SPP[4] + P[12][14]*SPP[3]; + nextP[0][15] = P[0][15] + P[1][15]*SF[6] + P[2][15]*SPP[7] + P[3][15]*SPP[6] + P[10][15]*SPP[5] + P[11][15]*SPP[4] + P[12][15]*SPP[3]; + nextP[0][16] = P[0][16] + P[1][16]*SF[6] + P[2][16]*SPP[7] + P[3][16]*SPP[6] + P[10][16]*SPP[5] + P[11][16]*SPP[4] + P[12][16]*SPP[3]; + nextP[0][17] = P[0][17] + P[1][17]*SF[6] + P[2][17]*SPP[7] + P[3][17]*SPP[6] + P[10][17]*SPP[5] + P[11][17]*SPP[4] + P[12][17]*SPP[3]; + nextP[0][18] = P[0][18] + P[1][18]*SF[6] + P[2][18]*SPP[7] + P[3][18]*SPP[6] + P[10][18]*SPP[5] + P[11][18]*SPP[4] + P[12][18]*SPP[3]; + nextP[0][19] = P[0][19] + P[1][19]*SF[6] + P[2][19]*SPP[7] + P[3][19]*SPP[6] + P[10][19]*SPP[5] + P[11][19]*SPP[4] + P[12][19]*SPP[3]; + nextP[0][20] = P[0][20] + P[1][20]*SF[6] + P[2][20]*SPP[7] + P[3][20]*SPP[6] + P[10][20]*SPP[5] + P[11][20]*SPP[4] + P[12][20]*SPP[3]; + nextP[1][0] = P[1][0] + SQ[8] + P[0][0]*SF[5] + P[2][0]*SF[4] + P[3][0]*SPP[7] + P[11][0]*SPP[3] - P[12][0]*SPP[4] - (P[10][0]*q0)/2 + SF[6]*(P[1][1] + P[0][1]*SF[5] + P[2][1]*SF[4] + P[3][1]*SPP[7] + P[11][1]*SPP[3] - P[12][1]*SPP[4] - (P[10][1]*q0)/2) + SPP[7]*(P[1][2] + P[0][2]*SF[5] + P[2][2]*SF[4] + P[3][2]*SPP[7] + P[11][2]*SPP[3] - P[12][2]*SPP[4] - (P[10][2]*q0)/2) + SPP[6]*(P[1][3] + P[0][3]*SF[5] + P[2][3]*SF[4] + P[3][3]*SPP[7] + P[11][3]*SPP[3] - P[12][3]*SPP[4] - (P[10][3]*q0)/2) + SPP[5]*(P[1][10] + P[0][10]*SF[5] + P[2][10]*SF[4] + P[3][10]*SPP[7] + P[11][10]*SPP[3] - P[12][10]*SPP[4] - (P[10][10]*q0)/2) + SPP[4]*(P[1][11] + P[0][11]*SF[5] + P[2][11]*SF[4] + P[3][11]*SPP[7] + P[11][11]*SPP[3] - P[12][11]*SPP[4] - (P[10][11]*q0)/2) + SPP[3]*(P[1][12] + P[0][12]*SF[5] + P[2][12]*SF[4] + P[3][12]*SPP[7] + P[11][12]*SPP[3] - P[12][12]*SPP[4] - (P[10][12]*q0)/2); + nextP[1][1] = P[1][1] + P[0][1]*SF[5] + P[2][1]*SF[4] + P[3][1]*SPP[7] + P[11][1]*SPP[3] - P[12][1]*SPP[4] + daxCov*SQ[9] - (P[10][1]*q0)/2 + SF[5]*(P[1][0] + P[0][0]*SF[5] + P[2][0]*SF[4] + P[3][0]*SPP[7] + P[11][0]*SPP[3] - P[12][0]*SPP[4] - (P[10][0]*q0)/2) + SF[4]*(P[1][2] + P[0][2]*SF[5] + P[2][2]*SF[4] + P[3][2]*SPP[7] + P[11][2]*SPP[3] - P[12][2]*SPP[4] - (P[10][2]*q0)/2) + SPP[7]*(P[1][3] + P[0][3]*SF[5] + P[2][3]*SF[4] + P[3][3]*SPP[7] + P[11][3]*SPP[3] - P[12][3]*SPP[4] - (P[10][3]*q0)/2) + SPP[3]*(P[1][11] + P[0][11]*SF[5] + P[2][11]*SF[4] + P[3][11]*SPP[7] + P[11][11]*SPP[3] - P[12][11]*SPP[4] - (P[10][11]*q0)/2) - SPP[4]*(P[1][12] + P[0][12]*SF[5] + P[2][12]*SF[4] + P[3][12]*SPP[7] + P[11][12]*SPP[3] - P[12][12]*SPP[4] - (P[10][12]*q0)/2) + (dayCov*sq(q3))/4 + (dazCov*sq(q2))/4 - (q0*(P[1][10] + P[0][10]*SF[5] + P[2][10]*SF[4] + P[3][10]*SPP[7] + P[11][10]*SPP[3] - P[12][10]*SPP[4] - (P[10][10]*q0)/2))/2; + nextP[1][2] = P[1][2] + SQ[5] + P[0][2]*SF[5] + P[2][2]*SF[4] + P[3][2]*SPP[7] + P[11][2]*SPP[3] - P[12][2]*SPP[4] - (P[10][2]*q0)/2 + SF[3]*(P[1][0] + P[0][0]*SF[5] + P[2][0]*SF[4] + P[3][0]*SPP[7] + P[11][0]*SPP[3] - P[12][0]*SPP[4] - (P[10][0]*q0)/2) + SF[5]*(P[1][3] + P[0][3]*SF[5] + P[2][3]*SF[4] + P[3][3]*SPP[7] + P[11][3]*SPP[3] - P[12][3]*SPP[4] - (P[10][3]*q0)/2) + SPP[6]*(P[1][1] + P[0][1]*SF[5] + P[2][1]*SF[4] + P[3][1]*SPP[7] + P[11][1]*SPP[3] - P[12][1]*SPP[4] - (P[10][1]*q0)/2) - SPP[3]*(P[1][10] + P[0][10]*SF[5] + P[2][10]*SF[4] + P[3][10]*SPP[7] + P[11][10]*SPP[3] - P[12][10]*SPP[4] - (P[10][10]*q0)/2) + SPP[5]*(P[1][12] + P[0][12]*SF[5] + P[2][12]*SF[4] + P[3][12]*SPP[7] + P[11][12]*SPP[3] - P[12][12]*SPP[4] - (P[10][12]*q0)/2) - (q0*(P[1][11] + P[0][11]*SF[5] + P[2][11]*SF[4] + P[3][11]*SPP[7] + P[11][11]*SPP[3] - P[12][11]*SPP[4] - (P[10][11]*q0)/2))/2; + nextP[1][3] = P[1][3] + SQ[4] + P[0][3]*SF[5] + P[2][3]*SF[4] + P[3][3]*SPP[7] + P[11][3]*SPP[3] - P[12][3]*SPP[4] - (P[10][3]*q0)/2 + SF[4]*(P[1][0] + P[0][0]*SF[5] + P[2][0]*SF[4] + P[3][0]*SPP[7] + P[11][0]*SPP[3] - P[12][0]*SPP[4] - (P[10][0]*q0)/2) + SF[3]*(P[1][1] + P[0][1]*SF[5] + P[2][1]*SF[4] + P[3][1]*SPP[7] + P[11][1]*SPP[3] - P[12][1]*SPP[4] - (P[10][1]*q0)/2) + SF[6]*(P[1][2] + P[0][2]*SF[5] + P[2][2]*SF[4] + P[3][2]*SPP[7] + P[11][2]*SPP[3] - P[12][2]*SPP[4] - (P[10][2]*q0)/2) + SPP[4]*(P[1][10] + P[0][10]*SF[5] + P[2][10]*SF[4] + P[3][10]*SPP[7] + P[11][10]*SPP[3] - P[12][10]*SPP[4] - (P[10][10]*q0)/2) - SPP[5]*(P[1][11] + P[0][11]*SF[5] + P[2][11]*SF[4] + P[3][11]*SPP[7] + P[11][11]*SPP[3] - P[12][11]*SPP[4] - (P[10][11]*q0)/2) - (q0*(P[1][12] + P[0][12]*SF[5] + P[2][12]*SF[4] + P[3][12]*SPP[7] + P[11][12]*SPP[3] - P[12][12]*SPP[4] - (P[10][12]*q0)/2))/2; + nextP[1][4] = P[1][4] + P[0][4]*SF[5] + P[2][4]*SF[4] + P[3][4]*SPP[7] + P[11][4]*SPP[3] - P[12][4]*SPP[4] - (P[10][4]*q0)/2 + SF[2]*(P[1][0] + P[0][0]*SF[5] + P[2][0]*SF[4] + P[3][0]*SPP[7] + P[11][0]*SPP[3] - P[12][0]*SPP[4] - (P[10][0]*q0)/2) + SF[0]*(P[1][1] + P[0][1]*SF[5] + P[2][1]*SF[4] + P[3][1]*SPP[7] + P[11][1]*SPP[3] - P[12][1]*SPP[4] - (P[10][1]*q0)/2) + SPP[0]*(P[1][2] + P[0][2]*SF[5] + P[2][2]*SF[4] + P[3][2]*SPP[7] + P[11][2]*SPP[3] - P[12][2]*SPP[4] - (P[10][2]*q0)/2) - SPP[2]*(P[1][3] + P[0][3]*SF[5] + P[2][3]*SF[4] + P[3][3]*SPP[7] + P[11][3]*SPP[3] - P[12][3]*SPP[4] - (P[10][3]*q0)/2); + nextP[1][5] = P[1][5] + P[0][5]*SF[5] + P[2][5]*SF[4] + P[3][5]*SPP[7] + P[11][5]*SPP[3] - P[12][5]*SPP[4] - (P[10][5]*q0)/2 + SF[1]*(P[1][0] + P[0][0]*SF[5] + P[2][0]*SF[4] + P[3][0]*SPP[7] + P[11][0]*SPP[3] - P[12][0]*SPP[4] - (P[10][0]*q0)/2) + SF[0]*(P[1][2] + P[0][2]*SF[5] + P[2][2]*SF[4] + P[3][2]*SPP[7] + P[11][2]*SPP[3] - P[12][2]*SPP[4] - (P[10][2]*q0)/2) + SF[2]*(P[1][3] + P[0][3]*SF[5] + P[2][3]*SF[4] + P[3][3]*SPP[7] + P[11][3]*SPP[3] - P[12][3]*SPP[4] - (P[10][3]*q0)/2) - SPP[0]*(P[1][1] + P[0][1]*SF[5] + P[2][1]*SF[4] + P[3][1]*SPP[7] + P[11][1]*SPP[3] - P[12][1]*SPP[4] - (P[10][1]*q0)/2); + nextP[1][6] = P[1][6] + P[0][6]*SF[5] + P[2][6]*SF[4] + P[3][6]*SPP[7] + P[11][6]*SPP[3] - P[12][6]*SPP[4] - (P[10][6]*q0)/2 + SF[1]*(P[1][1] + P[0][1]*SF[5] + P[2][1]*SF[4] + P[3][1]*SPP[7] + P[11][1]*SPP[3] - P[12][1]*SPP[4] - (P[10][1]*q0)/2) + SF[0]*(P[1][3] + P[0][3]*SF[5] + P[2][3]*SF[4] + P[3][3]*SPP[7] + P[11][3]*SPP[3] - P[12][3]*SPP[4] - (P[10][3]*q0)/2) + SPP[0]*(P[1][0] + P[0][0]*SF[5] + P[2][0]*SF[4] + P[3][0]*SPP[7] + P[11][0]*SPP[3] - P[12][0]*SPP[4] - (P[10][0]*q0)/2) - SPP[1]*(P[1][2] + P[0][2]*SF[5] + P[2][2]*SF[4] + P[3][2]*SPP[7] + P[11][2]*SPP[3] - P[12][2]*SPP[4] - (P[10][2]*q0)/2); + nextP[1][7] = P[1][7] + P[0][7]*SF[5] + P[2][7]*SF[4] + P[3][7]*SPP[7] + P[11][7]*SPP[3] - P[12][7]*SPP[4] - (P[10][7]*q0)/2 + dt*(P[1][4] + P[0][4]*SF[5] + P[2][4]*SF[4] + P[3][4]*SPP[7] + P[11][4]*SPP[3] - P[12][4]*SPP[4] - (P[10][4]*q0)/2); + nextP[1][8] = P[1][8] + P[0][8]*SF[5] + P[2][8]*SF[4] + P[3][8]*SPP[7] + P[11][8]*SPP[3] - P[12][8]*SPP[4] - (P[10][8]*q0)/2 + dt*(P[1][5] + P[0][5]*SF[5] + P[2][5]*SF[4] + P[3][5]*SPP[7] + P[11][5]*SPP[3] - P[12][5]*SPP[4] - (P[10][5]*q0)/2); + nextP[1][9] = P[1][9] + P[0][9]*SF[5] + P[2][9]*SF[4] + P[3][9]*SPP[7] + P[11][9]*SPP[3] - P[12][9]*SPP[4] - (P[10][9]*q0)/2 + dt*(P[1][6] + P[0][6]*SF[5] + P[2][6]*SF[4] + P[3][6]*SPP[7] + P[11][6]*SPP[3] - P[12][6]*SPP[4] - (P[10][6]*q0)/2); + nextP[1][10] = P[1][10] + P[0][10]*SF[5] + P[2][10]*SF[4] + P[3][10]*SPP[7] + P[11][10]*SPP[3] - P[12][10]*SPP[4] - (P[10][10]*q0)/2; + nextP[1][11] = P[1][11] + P[0][11]*SF[5] + P[2][11]*SF[4] + P[3][11]*SPP[7] + P[11][11]*SPP[3] - P[12][11]*SPP[4] - (P[10][11]*q0)/2; + nextP[1][12] = P[1][12] + P[0][12]*SF[5] + P[2][12]*SF[4] + P[3][12]*SPP[7] + P[11][12]*SPP[3] - P[12][12]*SPP[4] - (P[10][12]*q0)/2; + nextP[1][13] = P[1][13] + P[0][13]*SF[5] + P[2][13]*SF[4] + P[3][13]*SPP[7] + P[11][13]*SPP[3] - P[12][13]*SPP[4] - (P[10][13]*q0)/2; + nextP[1][14] = P[1][14] + P[0][14]*SF[5] + P[2][14]*SF[4] + P[3][14]*SPP[7] + P[11][14]*SPP[3] - P[12][14]*SPP[4] - (P[10][14]*q0)/2; + nextP[1][15] = P[1][15] + P[0][15]*SF[5] + P[2][15]*SF[4] + P[3][15]*SPP[7] + P[11][15]*SPP[3] - P[12][15]*SPP[4] - (P[10][15]*q0)/2; + nextP[1][16] = P[1][16] + P[0][16]*SF[5] + P[2][16]*SF[4] + P[3][16]*SPP[7] + P[11][16]*SPP[3] - P[12][16]*SPP[4] - (P[10][16]*q0)/2; + nextP[1][17] = P[1][17] + P[0][17]*SF[5] + P[2][17]*SF[4] + P[3][17]*SPP[7] + P[11][17]*SPP[3] - P[12][17]*SPP[4] - (P[10][17]*q0)/2; + nextP[1][18] = P[1][18] + P[0][18]*SF[5] + P[2][18]*SF[4] + P[3][18]*SPP[7] + P[11][18]*SPP[3] - P[12][18]*SPP[4] - (P[10][18]*q0)/2; + nextP[1][19] = P[1][19] + P[0][19]*SF[5] + P[2][19]*SF[4] + P[3][19]*SPP[7] + P[11][19]*SPP[3] - P[12][19]*SPP[4] - (P[10][19]*q0)/2; + nextP[1][20] = P[1][20] + P[0][20]*SF[5] + P[2][20]*SF[4] + P[3][20]*SPP[7] + P[11][20]*SPP[3] - P[12][20]*SPP[4] - (P[10][20]*q0)/2; + nextP[2][0] = P[2][0] + SQ[7] + P[0][0]*SF[3] + P[3][0]*SF[5] + P[1][0]*SPP[6] - P[10][0]*SPP[3] + P[12][0]*SPP[5] - (P[11][0]*q0)/2 + SF[6]*(P[2][1] + P[0][1]*SF[3] + P[3][1]*SF[5] + P[1][1]*SPP[6] - P[10][1]*SPP[3] + P[12][1]*SPP[5] - (P[11][1]*q0)/2) + SPP[7]*(P[2][2] + P[0][2]*SF[3] + P[3][2]*SF[5] + P[1][2]*SPP[6] - P[10][2]*SPP[3] + P[12][2]*SPP[5] - (P[11][2]*q0)/2) + SPP[6]*(P[2][3] + P[0][3]*SF[3] + P[3][3]*SF[5] + P[1][3]*SPP[6] - P[10][3]*SPP[3] + P[12][3]*SPP[5] - (P[11][3]*q0)/2) + SPP[5]*(P[2][10] + P[0][10]*SF[3] + P[3][10]*SF[5] + P[1][10]*SPP[6] - P[10][10]*SPP[3] + P[12][10]*SPP[5] - (P[11][10]*q0)/2) + SPP[4]*(P[2][11] + P[0][11]*SF[3] + P[3][11]*SF[5] + P[1][11]*SPP[6] - P[10][11]*SPP[3] + P[12][11]*SPP[5] - (P[11][11]*q0)/2) + SPP[3]*(P[2][12] + P[0][12]*SF[3] + P[3][12]*SF[5] + P[1][12]*SPP[6] - P[10][12]*SPP[3] + P[12][12]*SPP[5] - (P[11][12]*q0)/2); + nextP[2][1] = P[2][1] + SQ[5] + P[0][1]*SF[3] + P[3][1]*SF[5] + P[1][1]*SPP[6] - P[10][1]*SPP[3] + P[12][1]*SPP[5] - (P[11][1]*q0)/2 + SF[5]*(P[2][0] + P[0][0]*SF[3] + P[3][0]*SF[5] + P[1][0]*SPP[6] - P[10][0]*SPP[3] + P[12][0]*SPP[5] - (P[11][0]*q0)/2) + SF[4]*(P[2][2] + P[0][2]*SF[3] + P[3][2]*SF[5] + P[1][2]*SPP[6] - P[10][2]*SPP[3] + P[12][2]*SPP[5] - (P[11][2]*q0)/2) + SPP[7]*(P[2][3] + P[0][3]*SF[3] + P[3][3]*SF[5] + P[1][3]*SPP[6] - P[10][3]*SPP[3] + P[12][3]*SPP[5] - (P[11][3]*q0)/2) + SPP[3]*(P[2][11] + P[0][11]*SF[3] + P[3][11]*SF[5] + P[1][11]*SPP[6] - P[10][11]*SPP[3] + P[12][11]*SPP[5] - (P[11][11]*q0)/2) - SPP[4]*(P[2][12] + P[0][12]*SF[3] + P[3][12]*SF[5] + P[1][12]*SPP[6] - P[10][12]*SPP[3] + P[12][12]*SPP[5] - (P[11][12]*q0)/2) - (q0*(P[2][10] + P[0][10]*SF[3] + P[3][10]*SF[5] + P[1][10]*SPP[6] - P[10][10]*SPP[3] + P[12][10]*SPP[5] - (P[11][10]*q0)/2))/2; + nextP[2][2] = P[2][2] + P[0][2]*SF[3] + P[3][2]*SF[5] + P[1][2]*SPP[6] - P[10][2]*SPP[3] + P[12][2]*SPP[5] + dayCov*SQ[9] + (dazCov*SQ[10])/4 - (P[11][2]*q0)/2 + SF[3]*(P[2][0] + P[0][0]*SF[3] + P[3][0]*SF[5] + P[1][0]*SPP[6] - P[10][0]*SPP[3] + P[12][0]*SPP[5] - (P[11][0]*q0)/2) + SF[5]*(P[2][3] + P[0][3]*SF[3] + P[3][3]*SF[5] + P[1][3]*SPP[6] - P[10][3]*SPP[3] + P[12][3]*SPP[5] - (P[11][3]*q0)/2) + SPP[6]*(P[2][1] + P[0][1]*SF[3] + P[3][1]*SF[5] + P[1][1]*SPP[6] - P[10][1]*SPP[3] + P[12][1]*SPP[5] - (P[11][1]*q0)/2) - SPP[3]*(P[2][10] + P[0][10]*SF[3] + P[3][10]*SF[5] + P[1][10]*SPP[6] - P[10][10]*SPP[3] + P[12][10]*SPP[5] - (P[11][10]*q0)/2) + SPP[5]*(P[2][12] + P[0][12]*SF[3] + P[3][12]*SF[5] + P[1][12]*SPP[6] - P[10][12]*SPP[3] + P[12][12]*SPP[5] - (P[11][12]*q0)/2) + (daxCov*sq(q3))/4 - (q0*(P[2][11] + P[0][11]*SF[3] + P[3][11]*SF[5] + P[1][11]*SPP[6] - P[10][11]*SPP[3] + P[12][11]*SPP[5] - (P[11][11]*q0)/2))/2; + nextP[2][3] = P[2][3] + SQ[3] + P[0][3]*SF[3] + P[3][3]*SF[5] + P[1][3]*SPP[6] - P[10][3]*SPP[3] + P[12][3]*SPP[5] - (P[11][3]*q0)/2 + SF[4]*(P[2][0] + P[0][0]*SF[3] + P[3][0]*SF[5] + P[1][0]*SPP[6] - P[10][0]*SPP[3] + P[12][0]*SPP[5] - (P[11][0]*q0)/2) + SF[3]*(P[2][1] + P[0][1]*SF[3] + P[3][1]*SF[5] + P[1][1]*SPP[6] - P[10][1]*SPP[3] + P[12][1]*SPP[5] - (P[11][1]*q0)/2) + SF[6]*(P[2][2] + P[0][2]*SF[3] + P[3][2]*SF[5] + P[1][2]*SPP[6] - P[10][2]*SPP[3] + P[12][2]*SPP[5] - (P[11][2]*q0)/2) + SPP[4]*(P[2][10] + P[0][10]*SF[3] + P[3][10]*SF[5] + P[1][10]*SPP[6] - P[10][10]*SPP[3] + P[12][10]*SPP[5] - (P[11][10]*q0)/2) - SPP[5]*(P[2][11] + P[0][11]*SF[3] + P[3][11]*SF[5] + P[1][11]*SPP[6] - P[10][11]*SPP[3] + P[12][11]*SPP[5] - (P[11][11]*q0)/2) - (q0*(P[2][12] + P[0][12]*SF[3] + P[3][12]*SF[5] + P[1][12]*SPP[6] - P[10][12]*SPP[3] + P[12][12]*SPP[5] - (P[11][12]*q0)/2))/2; + nextP[2][4] = P[2][4] + P[0][4]*SF[3] + P[3][4]*SF[5] + P[1][4]*SPP[6] - P[10][4]*SPP[3] + P[12][4]*SPP[5] - (P[11][4]*q0)/2 + SF[2]*(P[2][0] + P[0][0]*SF[3] + P[3][0]*SF[5] + P[1][0]*SPP[6] - P[10][0]*SPP[3] + P[12][0]*SPP[5] - (P[11][0]*q0)/2) + SF[0]*(P[2][1] + P[0][1]*SF[3] + P[3][1]*SF[5] + P[1][1]*SPP[6] - P[10][1]*SPP[3] + P[12][1]*SPP[5] - (P[11][1]*q0)/2) + SPP[0]*(P[2][2] + P[0][2]*SF[3] + P[3][2]*SF[5] + P[1][2]*SPP[6] - P[10][2]*SPP[3] + P[12][2]*SPP[5] - (P[11][2]*q0)/2) - SPP[2]*(P[2][3] + P[0][3]*SF[3] + P[3][3]*SF[5] + P[1][3]*SPP[6] - P[10][3]*SPP[3] + P[12][3]*SPP[5] - (P[11][3]*q0)/2); + nextP[2][5] = P[2][5] + P[0][5]*SF[3] + P[3][5]*SF[5] + P[1][5]*SPP[6] - P[10][5]*SPP[3] + P[12][5]*SPP[5] - (P[11][5]*q0)/2 + SF[1]*(P[2][0] + P[0][0]*SF[3] + P[3][0]*SF[5] + P[1][0]*SPP[6] - P[10][0]*SPP[3] + P[12][0]*SPP[5] - (P[11][0]*q0)/2) + SF[0]*(P[2][2] + P[0][2]*SF[3] + P[3][2]*SF[5] + P[1][2]*SPP[6] - P[10][2]*SPP[3] + P[12][2]*SPP[5] - (P[11][2]*q0)/2) + SF[2]*(P[2][3] + P[0][3]*SF[3] + P[3][3]*SF[5] + P[1][3]*SPP[6] - P[10][3]*SPP[3] + P[12][3]*SPP[5] - (P[11][3]*q0)/2) - SPP[0]*(P[2][1] + P[0][1]*SF[3] + P[3][1]*SF[5] + P[1][1]*SPP[6] - P[10][1]*SPP[3] + P[12][1]*SPP[5] - (P[11][1]*q0)/2); + nextP[2][6] = P[2][6] + P[0][6]*SF[3] + P[3][6]*SF[5] + P[1][6]*SPP[6] - P[10][6]*SPP[3] + P[12][6]*SPP[5] - (P[11][6]*q0)/2 + SF[1]*(P[2][1] + P[0][1]*SF[3] + P[3][1]*SF[5] + P[1][1]*SPP[6] - P[10][1]*SPP[3] + P[12][1]*SPP[5] - (P[11][1]*q0)/2) + SF[0]*(P[2][3] + P[0][3]*SF[3] + P[3][3]*SF[5] + P[1][3]*SPP[6] - P[10][3]*SPP[3] + P[12][3]*SPP[5] - (P[11][3]*q0)/2) + SPP[0]*(P[2][0] + P[0][0]*SF[3] + P[3][0]*SF[5] + P[1][0]*SPP[6] - P[10][0]*SPP[3] + P[12][0]*SPP[5] - (P[11][0]*q0)/2) - SPP[1]*(P[2][2] + P[0][2]*SF[3] + P[3][2]*SF[5] + P[1][2]*SPP[6] - P[10][2]*SPP[3] + P[12][2]*SPP[5] - (P[11][2]*q0)/2); + nextP[2][7] = P[2][7] + P[0][7]*SF[3] + P[3][7]*SF[5] + P[1][7]*SPP[6] - P[10][7]*SPP[3] + P[12][7]*SPP[5] - (P[11][7]*q0)/2 + dt*(P[2][4] + P[0][4]*SF[3] + P[3][4]*SF[5] + P[1][4]*SPP[6] - P[10][4]*SPP[3] + P[12][4]*SPP[5] - (P[11][4]*q0)/2); + nextP[2][8] = P[2][8] + P[0][8]*SF[3] + P[3][8]*SF[5] + P[1][8]*SPP[6] - P[10][8]*SPP[3] + P[12][8]*SPP[5] - (P[11][8]*q0)/2 + dt*(P[2][5] + P[0][5]*SF[3] + P[3][5]*SF[5] + P[1][5]*SPP[6] - P[10][5]*SPP[3] + P[12][5]*SPP[5] - (P[11][5]*q0)/2); + nextP[2][9] = P[2][9] + P[0][9]*SF[3] + P[3][9]*SF[5] + P[1][9]*SPP[6] - P[10][9]*SPP[3] + P[12][9]*SPP[5] - (P[11][9]*q0)/2 + dt*(P[2][6] + P[0][6]*SF[3] + P[3][6]*SF[5] + P[1][6]*SPP[6] - P[10][6]*SPP[3] + P[12][6]*SPP[5] - (P[11][6]*q0)/2); + nextP[2][10] = P[2][10] + P[0][10]*SF[3] + P[3][10]*SF[5] + P[1][10]*SPP[6] - P[10][10]*SPP[3] + P[12][10]*SPP[5] - (P[11][10]*q0)/2; + nextP[2][11] = P[2][11] + P[0][11]*SF[3] + P[3][11]*SF[5] + P[1][11]*SPP[6] - P[10][11]*SPP[3] + P[12][11]*SPP[5] - (P[11][11]*q0)/2; + nextP[2][12] = P[2][12] + P[0][12]*SF[3] + P[3][12]*SF[5] + P[1][12]*SPP[6] - P[10][12]*SPP[3] + P[12][12]*SPP[5] - (P[11][12]*q0)/2; + nextP[2][13] = P[2][13] + P[0][13]*SF[3] + P[3][13]*SF[5] + P[1][13]*SPP[6] - P[10][13]*SPP[3] + P[12][13]*SPP[5] - (P[11][13]*q0)/2; + nextP[2][14] = P[2][14] + P[0][14]*SF[3] + P[3][14]*SF[5] + P[1][14]*SPP[6] - P[10][14]*SPP[3] + P[12][14]*SPP[5] - (P[11][14]*q0)/2; + nextP[2][15] = P[2][15] + P[0][15]*SF[3] + P[3][15]*SF[5] + P[1][15]*SPP[6] - P[10][15]*SPP[3] + P[12][15]*SPP[5] - (P[11][15]*q0)/2; + nextP[2][16] = P[2][16] + P[0][16]*SF[3] + P[3][16]*SF[5] + P[1][16]*SPP[6] - P[10][16]*SPP[3] + P[12][16]*SPP[5] - (P[11][16]*q0)/2; + nextP[2][17] = P[2][17] + P[0][17]*SF[3] + P[3][17]*SF[5] + P[1][17]*SPP[6] - P[10][17]*SPP[3] + P[12][17]*SPP[5] - (P[11][17]*q0)/2; + nextP[2][18] = P[2][18] + P[0][18]*SF[3] + P[3][18]*SF[5] + P[1][18]*SPP[6] - P[10][18]*SPP[3] + P[12][18]*SPP[5] - (P[11][18]*q0)/2; + nextP[2][19] = P[2][19] + P[0][19]*SF[3] + P[3][19]*SF[5] + P[1][19]*SPP[6] - P[10][19]*SPP[3] + P[12][19]*SPP[5] - (P[11][19]*q0)/2; + nextP[2][20] = P[2][20] + P[0][20]*SF[3] + P[3][20]*SF[5] + P[1][20]*SPP[6] - P[10][20]*SPP[3] + P[12][20]*SPP[5] - (P[11][20]*q0)/2; + nextP[3][0] = P[3][0] + SQ[6] + P[0][0]*SF[4] + P[1][0]*SF[3] + P[2][0]*SF[6] + P[10][0]*SPP[4] - P[11][0]*SPP[5] - (P[12][0]*q0)/2 + SF[6]*(P[3][1] + P[0][1]*SF[4] + P[1][1]*SF[3] + P[2][1]*SF[6] + P[10][1]*SPP[4] - P[11][1]*SPP[5] - (P[12][1]*q0)/2) + SPP[7]*(P[3][2] + P[0][2]*SF[4] + P[1][2]*SF[3] + P[2][2]*SF[6] + P[10][2]*SPP[4] - P[11][2]*SPP[5] - (P[12][2]*q0)/2) + SPP[6]*(P[3][3] + P[0][3]*SF[4] + P[1][3]*SF[3] + P[2][3]*SF[6] + P[10][3]*SPP[4] - P[11][3]*SPP[5] - (P[12][3]*q0)/2) + SPP[5]*(P[3][10] + P[0][10]*SF[4] + P[1][10]*SF[3] + P[2][10]*SF[6] + P[10][10]*SPP[4] - P[11][10]*SPP[5] - (P[12][10]*q0)/2) + SPP[4]*(P[3][11] + P[0][11]*SF[4] + P[1][11]*SF[3] + P[2][11]*SF[6] + P[10][11]*SPP[4] - P[11][11]*SPP[5] - (P[12][11]*q0)/2) + SPP[3]*(P[3][12] + P[0][12]*SF[4] + P[1][12]*SF[3] + P[2][12]*SF[6] + P[10][12]*SPP[4] - P[11][12]*SPP[5] - (P[12][12]*q0)/2); + nextP[3][1] = P[3][1] + SQ[4] + P[0][1]*SF[4] + P[1][1]*SF[3] + P[2][1]*SF[6] + P[10][1]*SPP[4] - P[11][1]*SPP[5] - (P[12][1]*q0)/2 + SF[5]*(P[3][0] + P[0][0]*SF[4] + P[1][0]*SF[3] + P[2][0]*SF[6] + P[10][0]*SPP[4] - P[11][0]*SPP[5] - (P[12][0]*q0)/2) + SF[4]*(P[3][2] + P[0][2]*SF[4] + P[1][2]*SF[3] + P[2][2]*SF[6] + P[10][2]*SPP[4] - P[11][2]*SPP[5] - (P[12][2]*q0)/2) + SPP[7]*(P[3][3] + P[0][3]*SF[4] + P[1][3]*SF[3] + P[2][3]*SF[6] + P[10][3]*SPP[4] - P[11][3]*SPP[5] - (P[12][3]*q0)/2) + SPP[3]*(P[3][11] + P[0][11]*SF[4] + P[1][11]*SF[3] + P[2][11]*SF[6] + P[10][11]*SPP[4] - P[11][11]*SPP[5] - (P[12][11]*q0)/2) - SPP[4]*(P[3][12] + P[0][12]*SF[4] + P[1][12]*SF[3] + P[2][12]*SF[6] + P[10][12]*SPP[4] - P[11][12]*SPP[5] - (P[12][12]*q0)/2) - (q0*(P[3][10] + P[0][10]*SF[4] + P[1][10]*SF[3] + P[2][10]*SF[6] + P[10][10]*SPP[4] - P[11][10]*SPP[5] - (P[12][10]*q0)/2))/2; + nextP[3][2] = P[3][2] + SQ[3] + P[0][2]*SF[4] + P[1][2]*SF[3] + P[2][2]*SF[6] + P[10][2]*SPP[4] - P[11][2]*SPP[5] - (P[12][2]*q0)/2 + SF[3]*(P[3][0] + P[0][0]*SF[4] + P[1][0]*SF[3] + P[2][0]*SF[6] + P[10][0]*SPP[4] - P[11][0]*SPP[5] - (P[12][0]*q0)/2) + SF[5]*(P[3][3] + P[0][3]*SF[4] + P[1][3]*SF[3] + P[2][3]*SF[6] + P[10][3]*SPP[4] - P[11][3]*SPP[5] - (P[12][3]*q0)/2) + SPP[6]*(P[3][1] + P[0][1]*SF[4] + P[1][1]*SF[3] + P[2][1]*SF[6] + P[10][1]*SPP[4] - P[11][1]*SPP[5] - (P[12][1]*q0)/2) - SPP[3]*(P[3][10] + P[0][10]*SF[4] + P[1][10]*SF[3] + P[2][10]*SF[6] + P[10][10]*SPP[4] - P[11][10]*SPP[5] - (P[12][10]*q0)/2) + SPP[5]*(P[3][12] + P[0][12]*SF[4] + P[1][12]*SF[3] + P[2][12]*SF[6] + P[10][12]*SPP[4] - P[11][12]*SPP[5] - (P[12][12]*q0)/2) - (q0*(P[3][11] + P[0][11]*SF[4] + P[1][11]*SF[3] + P[2][11]*SF[6] + P[10][11]*SPP[4] - P[11][11]*SPP[5] - (P[12][11]*q0)/2))/2; + nextP[3][3] = P[3][3] + P[0][3]*SF[4] + P[1][3]*SF[3] + P[2][3]*SF[6] + P[10][3]*SPP[4] - P[11][3]*SPP[5] + (dayCov*SQ[10])/4 + dazCov*SQ[9] - (P[12][3]*q0)/2 + SF[4]*(P[3][0] + P[0][0]*SF[4] + P[1][0]*SF[3] + P[2][0]*SF[6] + P[10][0]*SPP[4] - P[11][0]*SPP[5] - (P[12][0]*q0)/2) + SF[3]*(P[3][1] + P[0][1]*SF[4] + P[1][1]*SF[3] + P[2][1]*SF[6] + P[10][1]*SPP[4] - P[11][1]*SPP[5] - (P[12][1]*q0)/2) + SF[6]*(P[3][2] + P[0][2]*SF[4] + P[1][2]*SF[3] + P[2][2]*SF[6] + P[10][2]*SPP[4] - P[11][2]*SPP[5] - (P[12][2]*q0)/2) + SPP[4]*(P[3][10] + P[0][10]*SF[4] + P[1][10]*SF[3] + P[2][10]*SF[6] + P[10][10]*SPP[4] - P[11][10]*SPP[5] - (P[12][10]*q0)/2) - SPP[5]*(P[3][11] + P[0][11]*SF[4] + P[1][11]*SF[3] + P[2][11]*SF[6] + P[10][11]*SPP[4] - P[11][11]*SPP[5] - (P[12][11]*q0)/2) + (daxCov*sq(q2))/4 - (q0*(P[3][12] + P[0][12]*SF[4] + P[1][12]*SF[3] + P[2][12]*SF[6] + P[10][12]*SPP[4] - P[11][12]*SPP[5] - (P[12][12]*q0)/2))/2; + nextP[3][4] = P[3][4] + P[0][4]*SF[4] + P[1][4]*SF[3] + P[2][4]*SF[6] + P[10][4]*SPP[4] - P[11][4]*SPP[5] - (P[12][4]*q0)/2 + SF[2]*(P[3][0] + P[0][0]*SF[4] + P[1][0]*SF[3] + P[2][0]*SF[6] + P[10][0]*SPP[4] - P[11][0]*SPP[5] - (P[12][0]*q0)/2) + SF[0]*(P[3][1] + P[0][1]*SF[4] + P[1][1]*SF[3] + P[2][1]*SF[6] + P[10][1]*SPP[4] - P[11][1]*SPP[5] - (P[12][1]*q0)/2) + SPP[0]*(P[3][2] + P[0][2]*SF[4] + P[1][2]*SF[3] + P[2][2]*SF[6] + P[10][2]*SPP[4] - P[11][2]*SPP[5] - (P[12][2]*q0)/2) - SPP[2]*(P[3][3] + P[0][3]*SF[4] + P[1][3]*SF[3] + P[2][3]*SF[6] + P[10][3]*SPP[4] - P[11][3]*SPP[5] - (P[12][3]*q0)/2); + nextP[3][5] = P[3][5] + P[0][5]*SF[4] + P[1][5]*SF[3] + P[2][5]*SF[6] + P[10][5]*SPP[4] - P[11][5]*SPP[5] - (P[12][5]*q0)/2 + SF[1]*(P[3][0] + P[0][0]*SF[4] + P[1][0]*SF[3] + P[2][0]*SF[6] + P[10][0]*SPP[4] - P[11][0]*SPP[5] - (P[12][0]*q0)/2) + SF[0]*(P[3][2] + P[0][2]*SF[4] + P[1][2]*SF[3] + P[2][2]*SF[6] + P[10][2]*SPP[4] - P[11][2]*SPP[5] - (P[12][2]*q0)/2) + SF[2]*(P[3][3] + P[0][3]*SF[4] + P[1][3]*SF[3] + P[2][3]*SF[6] + P[10][3]*SPP[4] - P[11][3]*SPP[5] - (P[12][3]*q0)/2) - SPP[0]*(P[3][1] + P[0][1]*SF[4] + P[1][1]*SF[3] + P[2][1]*SF[6] + P[10][1]*SPP[4] - P[11][1]*SPP[5] - (P[12][1]*q0)/2); + nextP[3][6] = P[3][6] + P[0][6]*SF[4] + P[1][6]*SF[3] + P[2][6]*SF[6] + P[10][6]*SPP[4] - P[11][6]*SPP[5] - (P[12][6]*q0)/2 + SF[1]*(P[3][1] + P[0][1]*SF[4] + P[1][1]*SF[3] + P[2][1]*SF[6] + P[10][1]*SPP[4] - P[11][1]*SPP[5] - (P[12][1]*q0)/2) + SF[0]*(P[3][3] + P[0][3]*SF[4] + P[1][3]*SF[3] + P[2][3]*SF[6] + P[10][3]*SPP[4] - P[11][3]*SPP[5] - (P[12][3]*q0)/2) + SPP[0]*(P[3][0] + P[0][0]*SF[4] + P[1][0]*SF[3] + P[2][0]*SF[6] + P[10][0]*SPP[4] - P[11][0]*SPP[5] - (P[12][0]*q0)/2) - SPP[1]*(P[3][2] + P[0][2]*SF[4] + P[1][2]*SF[3] + P[2][2]*SF[6] + P[10][2]*SPP[4] - P[11][2]*SPP[5] - (P[12][2]*q0)/2); + nextP[3][7] = P[3][7] + P[0][7]*SF[4] + P[1][7]*SF[3] + P[2][7]*SF[6] + P[10][7]*SPP[4] - P[11][7]*SPP[5] - (P[12][7]*q0)/2 + dt*(P[3][4] + P[0][4]*SF[4] + P[1][4]*SF[3] + P[2][4]*SF[6] + P[10][4]*SPP[4] - P[11][4]*SPP[5] - (P[12][4]*q0)/2); + nextP[3][8] = P[3][8] + P[0][8]*SF[4] + P[1][8]*SF[3] + P[2][8]*SF[6] + P[10][8]*SPP[4] - P[11][8]*SPP[5] - (P[12][8]*q0)/2 + dt*(P[3][5] + P[0][5]*SF[4] + P[1][5]*SF[3] + P[2][5]*SF[6] + P[10][5]*SPP[4] - P[11][5]*SPP[5] - (P[12][5]*q0)/2); + nextP[3][9] = P[3][9] + P[0][9]*SF[4] + P[1][9]*SF[3] + P[2][9]*SF[6] + P[10][9]*SPP[4] - P[11][9]*SPP[5] - (P[12][9]*q0)/2 + dt*(P[3][6] + P[0][6]*SF[4] + P[1][6]*SF[3] + P[2][6]*SF[6] + P[10][6]*SPP[4] - P[11][6]*SPP[5] - (P[12][6]*q0)/2); + nextP[3][10] = P[3][10] + P[0][10]*SF[4] + P[1][10]*SF[3] + P[2][10]*SF[6] + P[10][10]*SPP[4] - P[11][10]*SPP[5] - (P[12][10]*q0)/2; + nextP[3][11] = P[3][11] + P[0][11]*SF[4] + P[1][11]*SF[3] + P[2][11]*SF[6] + P[10][11]*SPP[4] - P[11][11]*SPP[5] - (P[12][11]*q0)/2; + nextP[3][12] = P[3][12] + P[0][12]*SF[4] + P[1][12]*SF[3] + P[2][12]*SF[6] + P[10][12]*SPP[4] - P[11][12]*SPP[5] - (P[12][12]*q0)/2; + nextP[3][13] = P[3][13] + P[0][13]*SF[4] + P[1][13]*SF[3] + P[2][13]*SF[6] + P[10][13]*SPP[4] - P[11][13]*SPP[5] - (P[12][13]*q0)/2; + nextP[3][14] = P[3][14] + P[0][14]*SF[4] + P[1][14]*SF[3] + P[2][14]*SF[6] + P[10][14]*SPP[4] - P[11][14]*SPP[5] - (P[12][14]*q0)/2; + nextP[3][15] = P[3][15] + P[0][15]*SF[4] + P[1][15]*SF[3] + P[2][15]*SF[6] + P[10][15]*SPP[4] - P[11][15]*SPP[5] - (P[12][15]*q0)/2; + nextP[3][16] = P[3][16] + P[0][16]*SF[4] + P[1][16]*SF[3] + P[2][16]*SF[6] + P[10][16]*SPP[4] - P[11][16]*SPP[5] - (P[12][16]*q0)/2; + nextP[3][17] = P[3][17] + P[0][17]*SF[4] + P[1][17]*SF[3] + P[2][17]*SF[6] + P[10][17]*SPP[4] - P[11][17]*SPP[5] - (P[12][17]*q0)/2; + nextP[3][18] = P[3][18] + P[0][18]*SF[4] + P[1][18]*SF[3] + P[2][18]*SF[6] + P[10][18]*SPP[4] - P[11][18]*SPP[5] - (P[12][18]*q0)/2; + nextP[3][19] = P[3][19] + P[0][19]*SF[4] + P[1][19]*SF[3] + P[2][19]*SF[6] + P[10][19]*SPP[4] - P[11][19]*SPP[5] - (P[12][19]*q0)/2; + nextP[3][20] = P[3][20] + P[0][20]*SF[4] + P[1][20]*SF[3] + P[2][20]*SF[6] + P[10][20]*SPP[4] - P[11][20]*SPP[5] - (P[12][20]*q0)/2; + nextP[4][0] = P[4][0] + P[0][0]*SF[2] + P[1][0]*SF[0] + P[2][0]*SPP[0] - P[3][0]*SPP[2] + SF[6]*(P[4][1] + P[0][1]*SF[2] + P[1][1]*SF[0] + P[2][1]*SPP[0] - P[3][1]*SPP[2]) + SPP[7]*(P[4][2] + P[0][2]*SF[2] + P[1][2]*SF[0] + P[2][2]*SPP[0] - P[3][2]*SPP[2]) + SPP[6]*(P[4][3] + P[0][3]*SF[2] + P[1][3]*SF[0] + P[2][3]*SPP[0] - P[3][3]*SPP[2]) + SPP[5]*(P[4][10] + P[0][10]*SF[2] + P[1][10]*SF[0] + P[2][10]*SPP[0] - P[3][10]*SPP[2]) + SPP[4]*(P[4][11] + P[0][11]*SF[2] + P[1][11]*SF[0] + P[2][11]*SPP[0] - P[3][11]*SPP[2]) + SPP[3]*(P[4][12] + P[0][12]*SF[2] + P[1][12]*SF[0] + P[2][12]*SPP[0] - P[3][12]*SPP[2]); + nextP[4][1] = P[4][1] + P[0][1]*SF[2] + P[1][1]*SF[0] + P[2][1]*SPP[0] - P[3][1]*SPP[2] + SF[5]*(P[4][0] + P[0][0]*SF[2] + P[1][0]*SF[0] + P[2][0]*SPP[0] - P[3][0]*SPP[2]) + SF[4]*(P[4][2] + P[0][2]*SF[2] + P[1][2]*SF[0] + P[2][2]*SPP[0] - P[3][2]*SPP[2]) + SPP[7]*(P[4][3] + P[0][3]*SF[2] + P[1][3]*SF[0] + P[2][3]*SPP[0] - P[3][3]*SPP[2]) + SPP[3]*(P[4][11] + P[0][11]*SF[2] + P[1][11]*SF[0] + P[2][11]*SPP[0] - P[3][11]*SPP[2]) - SPP[4]*(P[4][12] + P[0][12]*SF[2] + P[1][12]*SF[0] + P[2][12]*SPP[0] - P[3][12]*SPP[2]) - (q0*(P[4][10] + P[0][10]*SF[2] + P[1][10]*SF[0] + P[2][10]*SPP[0] - P[3][10]*SPP[2]))/2; + nextP[4][2] = P[4][2] + P[0][2]*SF[2] + P[1][2]*SF[0] + P[2][2]*SPP[0] - P[3][2]*SPP[2] + SF[3]*(P[4][0] + P[0][0]*SF[2] + P[1][0]*SF[0] + P[2][0]*SPP[0] - P[3][0]*SPP[2]) + SF[5]*(P[4][3] + P[0][3]*SF[2] + P[1][3]*SF[0] + P[2][3]*SPP[0] - P[3][3]*SPP[2]) + SPP[6]*(P[4][1] + P[0][1]*SF[2] + P[1][1]*SF[0] + P[2][1]*SPP[0] - P[3][1]*SPP[2]) - SPP[3]*(P[4][10] + P[0][10]*SF[2] + P[1][10]*SF[0] + P[2][10]*SPP[0] - P[3][10]*SPP[2]) + SPP[5]*(P[4][12] + P[0][12]*SF[2] + P[1][12]*SF[0] + P[2][12]*SPP[0] - P[3][12]*SPP[2]) - (q0*(P[4][11] + P[0][11]*SF[2] + P[1][11]*SF[0] + P[2][11]*SPP[0] - P[3][11]*SPP[2]))/2; + nextP[4][3] = P[4][3] + P[0][3]*SF[2] + P[1][3]*SF[0] + P[2][3]*SPP[0] - P[3][3]*SPP[2] + SF[4]*(P[4][0] + P[0][0]*SF[2] + P[1][0]*SF[0] + P[2][0]*SPP[0] - P[3][0]*SPP[2]) + SF[3]*(P[4][1] + P[0][1]*SF[2] + P[1][1]*SF[0] + P[2][1]*SPP[0] - P[3][1]*SPP[2]) + SF[6]*(P[4][2] + P[0][2]*SF[2] + P[1][2]*SF[0] + P[2][2]*SPP[0] - P[3][2]*SPP[2]) + SPP[4]*(P[4][10] + P[0][10]*SF[2] + P[1][10]*SF[0] + P[2][10]*SPP[0] - P[3][10]*SPP[2]) - SPP[5]*(P[4][11] + P[0][11]*SF[2] + P[1][11]*SF[0] + P[2][11]*SPP[0] - P[3][11]*SPP[2]) - (q0*(P[4][12] + P[0][12]*SF[2] + P[1][12]*SF[0] + P[2][12]*SPP[0] - P[3][12]*SPP[2]))/2; + nextP[4][4] = P[4][4] + P[0][4]*SF[2] + P[1][4]*SF[0] + P[2][4]*SPP[0] - P[3][4]*SPP[2] + dvyCov*sq(SG[7] - 2*q0*q3) + dvzCov*sq(SG[6] + 2*q0*q2) + SF[2]*(P[4][0] + P[0][0]*SF[2] + P[1][0]*SF[0] + P[2][0]*SPP[0] - P[3][0]*SPP[2]) + SF[0]*(P[4][1] + P[0][1]*SF[2] + P[1][1]*SF[0] + P[2][1]*SPP[0] - P[3][1]*SPP[2]) + SPP[0]*(P[4][2] + P[0][2]*SF[2] + P[1][2]*SF[0] + P[2][2]*SPP[0] - P[3][2]*SPP[2]) - SPP[2]*(P[4][3] + P[0][3]*SF[2] + P[1][3]*SF[0] + P[2][3]*SPP[0] - P[3][3]*SPP[2]) + dvxCov*sq(SG[1] + SG[2] - SG[3] - SG[4]); + nextP[4][5] = P[4][5] + SQ[2] + P[0][5]*SF[2] + P[1][5]*SF[0] + P[2][5]*SPP[0] - P[3][5]*SPP[2] + SF[1]*(P[4][0] + P[0][0]*SF[2] + P[1][0]*SF[0] + P[2][0]*SPP[0] - P[3][0]*SPP[2]) + SF[0]*(P[4][2] + P[0][2]*SF[2] + P[1][2]*SF[0] + P[2][2]*SPP[0] - P[3][2]*SPP[2]) + SF[2]*(P[4][3] + P[0][3]*SF[2] + P[1][3]*SF[0] + P[2][3]*SPP[0] - P[3][3]*SPP[2]) - SPP[0]*(P[4][1] + P[0][1]*SF[2] + P[1][1]*SF[0] + P[2][1]*SPP[0] - P[3][1]*SPP[2]); + nextP[4][6] = P[4][6] + SQ[1] + P[0][6]*SF[2] + P[1][6]*SF[0] + P[2][6]*SPP[0] - P[3][6]*SPP[2] + SF[1]*(P[4][1] + P[0][1]*SF[2] + P[1][1]*SF[0] + P[2][1]*SPP[0] - P[3][1]*SPP[2]) + SF[0]*(P[4][3] + P[0][3]*SF[2] + P[1][3]*SF[0] + P[2][3]*SPP[0] - P[3][3]*SPP[2]) + SPP[0]*(P[4][0] + P[0][0]*SF[2] + P[1][0]*SF[0] + P[2][0]*SPP[0] - P[3][0]*SPP[2]) - SPP[1]*(P[4][2] + P[0][2]*SF[2] + P[1][2]*SF[0] + P[2][2]*SPP[0] - P[3][2]*SPP[2]); + nextP[4][7] = P[4][7] + P[0][7]*SF[2] + P[1][7]*SF[0] + P[2][7]*SPP[0] - P[3][7]*SPP[2] + dt*(P[4][4] + P[0][4]*SF[2] + P[1][4]*SF[0] + P[2][4]*SPP[0] - P[3][4]*SPP[2]); + nextP[4][8] = P[4][8] + P[0][8]*SF[2] + P[1][8]*SF[0] + P[2][8]*SPP[0] - P[3][8]*SPP[2] + dt*(P[4][5] + P[0][5]*SF[2] + P[1][5]*SF[0] + P[2][5]*SPP[0] - P[3][5]*SPP[2]); + nextP[4][9] = P[4][9] + P[0][9]*SF[2] + P[1][9]*SF[0] + P[2][9]*SPP[0] - P[3][9]*SPP[2] + dt*(P[4][6] + P[0][6]*SF[2] + P[1][6]*SF[0] + P[2][6]*SPP[0] - P[3][6]*SPP[2]); + nextP[4][10] = P[4][10] + P[0][10]*SF[2] + P[1][10]*SF[0] + P[2][10]*SPP[0] - P[3][10]*SPP[2]; + nextP[4][11] = P[4][11] + P[0][11]*SF[2] + P[1][11]*SF[0] + P[2][11]*SPP[0] - P[3][11]*SPP[2]; + nextP[4][12] = P[4][12] + P[0][12]*SF[2] + P[1][12]*SF[0] + P[2][12]*SPP[0] - P[3][12]*SPP[2]; + nextP[4][13] = P[4][13] + P[0][13]*SF[2] + P[1][13]*SF[0] + P[2][13]*SPP[0] - P[3][13]*SPP[2]; + nextP[4][14] = P[4][14] + P[0][14]*SF[2] + P[1][14]*SF[0] + P[2][14]*SPP[0] - P[3][14]*SPP[2]; + nextP[4][15] = P[4][15] + P[0][15]*SF[2] + P[1][15]*SF[0] + P[2][15]*SPP[0] - P[3][15]*SPP[2]; + nextP[4][16] = P[4][16] + P[0][16]*SF[2] + P[1][16]*SF[0] + P[2][16]*SPP[0] - P[3][16]*SPP[2]; + nextP[4][17] = P[4][17] + P[0][17]*SF[2] + P[1][17]*SF[0] + P[2][17]*SPP[0] - P[3][17]*SPP[2]; + nextP[4][18] = P[4][18] + P[0][18]*SF[2] + P[1][18]*SF[0] + P[2][18]*SPP[0] - P[3][18]*SPP[2]; + nextP[4][19] = P[4][19] + P[0][19]*SF[2] + P[1][19]*SF[0] + P[2][19]*SPP[0] - P[3][19]*SPP[2]; + nextP[4][20] = P[4][20] + P[0][20]*SF[2] + P[1][20]*SF[0] + P[2][20]*SPP[0] - P[3][20]*SPP[2]; + nextP[5][0] = P[5][0] + P[0][0]*SF[1] + P[2][0]*SF[0] + P[3][0]*SF[2] - P[1][0]*SPP[0] + SF[6]*(P[5][1] + P[0][1]*SF[1] + P[2][1]*SF[0] + P[3][1]*SF[2] - P[1][1]*SPP[0]) + SPP[7]*(P[5][2] + P[0][2]*SF[1] + P[2][2]*SF[0] + P[3][2]*SF[2] - P[1][2]*SPP[0]) + SPP[6]*(P[5][3] + P[0][3]*SF[1] + P[2][3]*SF[0] + P[3][3]*SF[2] - P[1][3]*SPP[0]) + SPP[5]*(P[5][10] + P[0][10]*SF[1] + P[2][10]*SF[0] + P[3][10]*SF[2] - P[1][10]*SPP[0]) + SPP[4]*(P[5][11] + P[0][11]*SF[1] + P[2][11]*SF[0] + P[3][11]*SF[2] - P[1][11]*SPP[0]) + SPP[3]*(P[5][12] + P[0][12]*SF[1] + P[2][12]*SF[0] + P[3][12]*SF[2] - P[1][12]*SPP[0]); + nextP[5][1] = P[5][1] + P[0][1]*SF[1] + P[2][1]*SF[0] + P[3][1]*SF[2] - P[1][1]*SPP[0] + SF[5]*(P[5][0] + P[0][0]*SF[1] + P[2][0]*SF[0] + P[3][0]*SF[2] - P[1][0]*SPP[0]) + SF[4]*(P[5][2] + P[0][2]*SF[1] + P[2][2]*SF[0] + P[3][2]*SF[2] - P[1][2]*SPP[0]) + SPP[7]*(P[5][3] + P[0][3]*SF[1] + P[2][3]*SF[0] + P[3][3]*SF[2] - P[1][3]*SPP[0]) + SPP[3]*(P[5][11] + P[0][11]*SF[1] + P[2][11]*SF[0] + P[3][11]*SF[2] - P[1][11]*SPP[0]) - SPP[4]*(P[5][12] + P[0][12]*SF[1] + P[2][12]*SF[0] + P[3][12]*SF[2] - P[1][12]*SPP[0]) - (q0*(P[5][10] + P[0][10]*SF[1] + P[2][10]*SF[0] + P[3][10]*SF[2] - P[1][10]*SPP[0]))/2; + nextP[5][2] = P[5][2] + P[0][2]*SF[1] + P[2][2]*SF[0] + P[3][2]*SF[2] - P[1][2]*SPP[0] + SF[3]*(P[5][0] + P[0][0]*SF[1] + P[2][0]*SF[0] + P[3][0]*SF[2] - P[1][0]*SPP[0]) + SF[5]*(P[5][3] + P[0][3]*SF[1] + P[2][3]*SF[0] + P[3][3]*SF[2] - P[1][3]*SPP[0]) + SPP[6]*(P[5][1] + P[0][1]*SF[1] + P[2][1]*SF[0] + P[3][1]*SF[2] - P[1][1]*SPP[0]) - SPP[3]*(P[5][10] + P[0][10]*SF[1] + P[2][10]*SF[0] + P[3][10]*SF[2] - P[1][10]*SPP[0]) + SPP[5]*(P[5][12] + P[0][12]*SF[1] + P[2][12]*SF[0] + P[3][12]*SF[2] - P[1][12]*SPP[0]) - (q0*(P[5][11] + P[0][11]*SF[1] + P[2][11]*SF[0] + P[3][11]*SF[2] - P[1][11]*SPP[0]))/2; + nextP[5][3] = P[5][3] + P[0][3]*SF[1] + P[2][3]*SF[0] + P[3][3]*SF[2] - P[1][3]*SPP[0] + SF[4]*(P[5][0] + P[0][0]*SF[1] + P[2][0]*SF[0] + P[3][0]*SF[2] - P[1][0]*SPP[0]) + SF[3]*(P[5][1] + P[0][1]*SF[1] + P[2][1]*SF[0] + P[3][1]*SF[2] - P[1][1]*SPP[0]) + SF[6]*(P[5][2] + P[0][2]*SF[1] + P[2][2]*SF[0] + P[3][2]*SF[2] - P[1][2]*SPP[0]) + SPP[4]*(P[5][10] + P[0][10]*SF[1] + P[2][10]*SF[0] + P[3][10]*SF[2] - P[1][10]*SPP[0]) - SPP[5]*(P[5][11] + P[0][11]*SF[1] + P[2][11]*SF[0] + P[3][11]*SF[2] - P[1][11]*SPP[0]) - (q0*(P[5][12] + P[0][12]*SF[1] + P[2][12]*SF[0] + P[3][12]*SF[2] - P[1][12]*SPP[0]))/2; + nextP[5][4] = P[5][4] + SQ[2] + P[0][4]*SF[1] + P[2][4]*SF[0] + P[3][4]*SF[2] - P[1][4]*SPP[0] + SF[2]*(P[5][0] + P[0][0]*SF[1] + P[2][0]*SF[0] + P[3][0]*SF[2] - P[1][0]*SPP[0]) + SF[0]*(P[5][1] + P[0][1]*SF[1] + P[2][1]*SF[0] + P[3][1]*SF[2] - P[1][1]*SPP[0]) + SPP[0]*(P[5][2] + P[0][2]*SF[1] + P[2][2]*SF[0] + P[3][2]*SF[2] - P[1][2]*SPP[0]) - SPP[2]*(P[5][3] + P[0][3]*SF[1] + P[2][3]*SF[0] + P[3][3]*SF[2] - P[1][3]*SPP[0]); + nextP[5][5] = P[5][5] + P[0][5]*SF[1] + P[2][5]*SF[0] + P[3][5]*SF[2] - P[1][5]*SPP[0] + dvxCov*sq(SG[7] + 2*q0*q3) + dvzCov*sq(SG[5] - 2*q0*q1) + SF[1]*(P[5][0] + P[0][0]*SF[1] + P[2][0]*SF[0] + P[3][0]*SF[2] - P[1][0]*SPP[0]) + SF[0]*(P[5][2] + P[0][2]*SF[1] + P[2][2]*SF[0] + P[3][2]*SF[2] - P[1][2]*SPP[0]) + SF[2]*(P[5][3] + P[0][3]*SF[1] + P[2][3]*SF[0] + P[3][3]*SF[2] - P[1][3]*SPP[0]) - SPP[0]*(P[5][1] + P[0][1]*SF[1] + P[2][1]*SF[0] + P[3][1]*SF[2] - P[1][1]*SPP[0]) + dvyCov*sq(SG[1] - SG[2] + SG[3] - SG[4]); + nextP[5][6] = P[5][6] + SQ[0] + P[0][6]*SF[1] + P[2][6]*SF[0] + P[3][6]*SF[2] - P[1][6]*SPP[0] + SF[1]*(P[5][1] + P[0][1]*SF[1] + P[2][1]*SF[0] + P[3][1]*SF[2] - P[1][1]*SPP[0]) + SF[0]*(P[5][3] + P[0][3]*SF[1] + P[2][3]*SF[0] + P[3][3]*SF[2] - P[1][3]*SPP[0]) + SPP[0]*(P[5][0] + P[0][0]*SF[1] + P[2][0]*SF[0] + P[3][0]*SF[2] - P[1][0]*SPP[0]) - SPP[1]*(P[5][2] + P[0][2]*SF[1] + P[2][2]*SF[0] + P[3][2]*SF[2] - P[1][2]*SPP[0]); + nextP[5][7] = P[5][7] + P[0][7]*SF[1] + P[2][7]*SF[0] + P[3][7]*SF[2] - P[1][7]*SPP[0] + dt*(P[5][4] + P[0][4]*SF[1] + P[2][4]*SF[0] + P[3][4]*SF[2] - P[1][4]*SPP[0]); + nextP[5][8] = P[5][8] + P[0][8]*SF[1] + P[2][8]*SF[0] + P[3][8]*SF[2] - P[1][8]*SPP[0] + dt*(P[5][5] + P[0][5]*SF[1] + P[2][5]*SF[0] + P[3][5]*SF[2] - P[1][5]*SPP[0]); + nextP[5][9] = P[5][9] + P[0][9]*SF[1] + P[2][9]*SF[0] + P[3][9]*SF[2] - P[1][9]*SPP[0] + dt*(P[5][6] + P[0][6]*SF[1] + P[2][6]*SF[0] + P[3][6]*SF[2] - P[1][6]*SPP[0]); + nextP[5][10] = P[5][10] + P[0][10]*SF[1] + P[2][10]*SF[0] + P[3][10]*SF[2] - P[1][10]*SPP[0]; + nextP[5][11] = P[5][11] + P[0][11]*SF[1] + P[2][11]*SF[0] + P[3][11]*SF[2] - P[1][11]*SPP[0]; + nextP[5][12] = P[5][12] + P[0][12]*SF[1] + P[2][12]*SF[0] + P[3][12]*SF[2] - P[1][12]*SPP[0]; + nextP[5][13] = P[5][13] + P[0][13]*SF[1] + P[2][13]*SF[0] + P[3][13]*SF[2] - P[1][13]*SPP[0]; + nextP[5][14] = P[5][14] + P[0][14]*SF[1] + P[2][14]*SF[0] + P[3][14]*SF[2] - P[1][14]*SPP[0]; + nextP[5][15] = P[5][15] + P[0][15]*SF[1] + P[2][15]*SF[0] + P[3][15]*SF[2] - P[1][15]*SPP[0]; + nextP[5][16] = P[5][16] + P[0][16]*SF[1] + P[2][16]*SF[0] + P[3][16]*SF[2] - P[1][16]*SPP[0]; + nextP[5][17] = P[5][17] + P[0][17]*SF[1] + P[2][17]*SF[0] + P[3][17]*SF[2] - P[1][17]*SPP[0]; + nextP[5][18] = P[5][18] + P[0][18]*SF[1] + P[2][18]*SF[0] + P[3][18]*SF[2] - P[1][18]*SPP[0]; + nextP[5][19] = P[5][19] + P[0][19]*SF[1] + P[2][19]*SF[0] + P[3][19]*SF[2] - P[1][19]*SPP[0]; + nextP[5][20] = P[5][20] + P[0][20]*SF[1] + P[2][20]*SF[0] + P[3][20]*SF[2] - P[1][20]*SPP[0]; + nextP[6][0] = P[6][0] + P[1][0]*SF[1] + P[3][0]*SF[0] + P[0][0]*SPP[0] - P[2][0]*SPP[1] + SF[6]*(P[6][1] + P[1][1]*SF[1] + P[3][1]*SF[0] + P[0][1]*SPP[0] - P[2][1]*SPP[1]) + SPP[7]*(P[6][2] + P[1][2]*SF[1] + P[3][2]*SF[0] + P[0][2]*SPP[0] - P[2][2]*SPP[1]) + SPP[6]*(P[6][3] + P[1][3]*SF[1] + P[3][3]*SF[0] + P[0][3]*SPP[0] - P[2][3]*SPP[1]) + SPP[5]*(P[6][10] + P[1][10]*SF[1] + P[3][10]*SF[0] + P[0][10]*SPP[0] - P[2][10]*SPP[1]) + SPP[4]*(P[6][11] + P[1][11]*SF[1] + P[3][11]*SF[0] + P[0][11]*SPP[0] - P[2][11]*SPP[1]) + SPP[3]*(P[6][12] + P[1][12]*SF[1] + P[3][12]*SF[0] + P[0][12]*SPP[0] - P[2][12]*SPP[1]); + nextP[6][1] = P[6][1] + P[1][1]*SF[1] + P[3][1]*SF[0] + P[0][1]*SPP[0] - P[2][1]*SPP[1] + SF[5]*(P[6][0] + P[1][0]*SF[1] + P[3][0]*SF[0] + P[0][0]*SPP[0] - P[2][0]*SPP[1]) + SF[4]*(P[6][2] + P[1][2]*SF[1] + P[3][2]*SF[0] + P[0][2]*SPP[0] - P[2][2]*SPP[1]) + SPP[7]*(P[6][3] + P[1][3]*SF[1] + P[3][3]*SF[0] + P[0][3]*SPP[0] - P[2][3]*SPP[1]) + SPP[3]*(P[6][11] + P[1][11]*SF[1] + P[3][11]*SF[0] + P[0][11]*SPP[0] - P[2][11]*SPP[1]) - SPP[4]*(P[6][12] + P[1][12]*SF[1] + P[3][12]*SF[0] + P[0][12]*SPP[0] - P[2][12]*SPP[1]) - (q0*(P[6][10] + P[1][10]*SF[1] + P[3][10]*SF[0] + P[0][10]*SPP[0] - P[2][10]*SPP[1]))/2; + nextP[6][2] = P[6][2] + P[1][2]*SF[1] + P[3][2]*SF[0] + P[0][2]*SPP[0] - P[2][2]*SPP[1] + SF[3]*(P[6][0] + P[1][0]*SF[1] + P[3][0]*SF[0] + P[0][0]*SPP[0] - P[2][0]*SPP[1]) + SF[5]*(P[6][3] + P[1][3]*SF[1] + P[3][3]*SF[0] + P[0][3]*SPP[0] - P[2][3]*SPP[1]) + SPP[6]*(P[6][1] + P[1][1]*SF[1] + P[3][1]*SF[0] + P[0][1]*SPP[0] - P[2][1]*SPP[1]) - SPP[3]*(P[6][10] + P[1][10]*SF[1] + P[3][10]*SF[0] + P[0][10]*SPP[0] - P[2][10]*SPP[1]) + SPP[5]*(P[6][12] + P[1][12]*SF[1] + P[3][12]*SF[0] + P[0][12]*SPP[0] - P[2][12]*SPP[1]) - (q0*(P[6][11] + P[1][11]*SF[1] + P[3][11]*SF[0] + P[0][11]*SPP[0] - P[2][11]*SPP[1]))/2; + nextP[6][3] = P[6][3] + P[1][3]*SF[1] + P[3][3]*SF[0] + P[0][3]*SPP[0] - P[2][3]*SPP[1] + SF[4]*(P[6][0] + P[1][0]*SF[1] + P[3][0]*SF[0] + P[0][0]*SPP[0] - P[2][0]*SPP[1]) + SF[3]*(P[6][1] + P[1][1]*SF[1] + P[3][1]*SF[0] + P[0][1]*SPP[0] - P[2][1]*SPP[1]) + SF[6]*(P[6][2] + P[1][2]*SF[1] + P[3][2]*SF[0] + P[0][2]*SPP[0] - P[2][2]*SPP[1]) + SPP[4]*(P[6][10] + P[1][10]*SF[1] + P[3][10]*SF[0] + P[0][10]*SPP[0] - P[2][10]*SPP[1]) - SPP[5]*(P[6][11] + P[1][11]*SF[1] + P[3][11]*SF[0] + P[0][11]*SPP[0] - P[2][11]*SPP[1]) - (q0*(P[6][12] + P[1][12]*SF[1] + P[3][12]*SF[0] + P[0][12]*SPP[0] - P[2][12]*SPP[1]))/2; + nextP[6][4] = P[6][4] + SQ[1] + P[1][4]*SF[1] + P[3][4]*SF[0] + P[0][4]*SPP[0] - P[2][4]*SPP[1] + SF[2]*(P[6][0] + P[1][0]*SF[1] + P[3][0]*SF[0] + P[0][0]*SPP[0] - P[2][0]*SPP[1]) + SF[0]*(P[6][1] + P[1][1]*SF[1] + P[3][1]*SF[0] + P[0][1]*SPP[0] - P[2][1]*SPP[1]) + SPP[0]*(P[6][2] + P[1][2]*SF[1] + P[3][2]*SF[0] + P[0][2]*SPP[0] - P[2][2]*SPP[1]) - SPP[2]*(P[6][3] + P[1][3]*SF[1] + P[3][3]*SF[0] + P[0][3]*SPP[0] - P[2][3]*SPP[1]); + nextP[6][5] = P[6][5] + SQ[0] + P[1][5]*SF[1] + P[3][5]*SF[0] + P[0][5]*SPP[0] - P[2][5]*SPP[1] + SF[1]*(P[6][0] + P[1][0]*SF[1] + P[3][0]*SF[0] + P[0][0]*SPP[0] - P[2][0]*SPP[1]) + SF[0]*(P[6][2] + P[1][2]*SF[1] + P[3][2]*SF[0] + P[0][2]*SPP[0] - P[2][2]*SPP[1]) + SF[2]*(P[6][3] + P[1][3]*SF[1] + P[3][3]*SF[0] + P[0][3]*SPP[0] - P[2][3]*SPP[1]) - SPP[0]*(P[6][1] + P[1][1]*SF[1] + P[3][1]*SF[0] + P[0][1]*SPP[0] - P[2][1]*SPP[1]); + nextP[6][6] = P[6][6] + P[1][6]*SF[1] + P[3][6]*SF[0] + P[0][6]*SPP[0] - P[2][6]*SPP[1] + dvxCov*sq(SG[6] - 2*q0*q2) + dvyCov*sq(SG[5] + 2*q0*q1) + SF[1]*(P[6][1] + P[1][1]*SF[1] + P[3][1]*SF[0] + P[0][1]*SPP[0] - P[2][1]*SPP[1]) + SF[0]*(P[6][3] + P[1][3]*SF[1] + P[3][3]*SF[0] + P[0][3]*SPP[0] - P[2][3]*SPP[1]) + SPP[0]*(P[6][0] + P[1][0]*SF[1] + P[3][0]*SF[0] + P[0][0]*SPP[0] - P[2][0]*SPP[1]) - SPP[1]*(P[6][2] + P[1][2]*SF[1] + P[3][2]*SF[0] + P[0][2]*SPP[0] - P[2][2]*SPP[1]) + dvzCov*sq(SG[1] - SG[2] - SG[3] + SG[4]); + nextP[6][7] = P[6][7] + P[1][7]*SF[1] + P[3][7]*SF[0] + P[0][7]*SPP[0] - P[2][7]*SPP[1] + dt*(P[6][4] + P[1][4]*SF[1] + P[3][4]*SF[0] + P[0][4]*SPP[0] - P[2][4]*SPP[1]); + nextP[6][8] = P[6][8] + P[1][8]*SF[1] + P[3][8]*SF[0] + P[0][8]*SPP[0] - P[2][8]*SPP[1] + dt*(P[6][5] + P[1][5]*SF[1] + P[3][5]*SF[0] + P[0][5]*SPP[0] - P[2][5]*SPP[1]); + nextP[6][9] = P[6][9] + P[1][9]*SF[1] + P[3][9]*SF[0] + P[0][9]*SPP[0] - P[2][9]*SPP[1] + dt*(P[6][6] + P[1][6]*SF[1] + P[3][6]*SF[0] + P[0][6]*SPP[0] - P[2][6]*SPP[1]); + nextP[6][10] = P[6][10] + P[1][10]*SF[1] + P[3][10]*SF[0] + P[0][10]*SPP[0] - P[2][10]*SPP[1]; + nextP[6][11] = P[6][11] + P[1][11]*SF[1] + P[3][11]*SF[0] + P[0][11]*SPP[0] - P[2][11]*SPP[1]; + nextP[6][12] = P[6][12] + P[1][12]*SF[1] + P[3][12]*SF[0] + P[0][12]*SPP[0] - P[2][12]*SPP[1]; + nextP[6][13] = P[6][13] + P[1][13]*SF[1] + P[3][13]*SF[0] + P[0][13]*SPP[0] - P[2][13]*SPP[1]; + nextP[6][14] = P[6][14] + P[1][14]*SF[1] + P[3][14]*SF[0] + P[0][14]*SPP[0] - P[2][14]*SPP[1]; + nextP[6][15] = P[6][15] + P[1][15]*SF[1] + P[3][15]*SF[0] + P[0][15]*SPP[0] - P[2][15]*SPP[1]; + nextP[6][16] = P[6][16] + P[1][16]*SF[1] + P[3][16]*SF[0] + P[0][16]*SPP[0] - P[2][16]*SPP[1]; + nextP[6][17] = P[6][17] + P[1][17]*SF[1] + P[3][17]*SF[0] + P[0][17]*SPP[0] - P[2][17]*SPP[1]; + nextP[6][18] = P[6][18] + P[1][18]*SF[1] + P[3][18]*SF[0] + P[0][18]*SPP[0] - P[2][18]*SPP[1]; + nextP[6][19] = P[6][19] + P[1][19]*SF[1] + P[3][19]*SF[0] + P[0][19]*SPP[0] - P[2][19]*SPP[1]; + nextP[6][20] = P[6][20] + P[1][20]*SF[1] + P[3][20]*SF[0] + P[0][20]*SPP[0] - P[2][20]*SPP[1]; + nextP[7][0] = P[7][0] + P[4][0]*dt + SF[6]*(P[7][1] + P[4][1]*dt) + SPP[7]*(P[7][2] + P[4][2]*dt) + SPP[6]*(P[7][3] + P[4][3]*dt) + SPP[5]*(P[7][10] + P[4][10]*dt) + SPP[4]*(P[7][11] + P[4][11]*dt) + SPP[3]*(P[7][12] + P[4][12]*dt); + nextP[7][1] = P[7][1] + P[4][1]*dt + SF[5]*(P[7][0] + P[4][0]*dt) + SF[4]*(P[7][2] + P[4][2]*dt) + SPP[7]*(P[7][3] + P[4][3]*dt) + SPP[3]*(P[7][11] + P[4][11]*dt) - SPP[4]*(P[7][12] + P[4][12]*dt) - (q0*(P[7][10] + P[4][10]*dt))/2; + nextP[7][2] = P[7][2] + P[4][2]*dt + SF[3]*(P[7][0] + P[4][0]*dt) + SF[5]*(P[7][3] + P[4][3]*dt) + SPP[6]*(P[7][1] + P[4][1]*dt) - SPP[3]*(P[7][10] + P[4][10]*dt) + SPP[5]*(P[7][12] + P[4][12]*dt) - (q0*(P[7][11] + P[4][11]*dt))/2; + nextP[7][3] = P[7][3] + P[4][3]*dt + SF[4]*(P[7][0] + P[4][0]*dt) + SF[3]*(P[7][1] + P[4][1]*dt) + SF[6]*(P[7][2] + P[4][2]*dt) + SPP[4]*(P[7][10] + P[4][10]*dt) - SPP[5]*(P[7][11] + P[4][11]*dt) - (q0*(P[7][12] + P[4][12]*dt))/2; + nextP[7][4] = P[7][4] + P[4][4]*dt + SF[0]*(P[7][1] + P[4][1]*dt) + SF[2]*(P[7][0] + P[4][0]*dt) + SPP[0]*(P[7][2] + P[4][2]*dt) - SPP[2]*(P[7][3] + P[4][3]*dt); + nextP[7][5] = P[7][5] + P[4][5]*dt + SF[1]*(P[7][0] + P[4][0]*dt) + SF[0]*(P[7][2] + P[4][2]*dt) + SF[2]*(P[7][3] + P[4][3]*dt) - SPP[0]*(P[7][1] + P[4][1]*dt); + nextP[7][6] = P[7][6] + P[4][6]*dt + SF[1]*(P[7][1] + P[4][1]*dt) + SF[0]*(P[7][3] + P[4][3]*dt) + SPP[0]*(P[7][0] + P[4][0]*dt) - SPP[1]*(P[7][2] + P[4][2]*dt); + nextP[7][7] = P[7][7] + P[4][7]*dt + dt*(P[7][4] + P[4][4]*dt); + nextP[7][8] = P[7][8] + P[4][8]*dt + dt*(P[7][5] + P[4][5]*dt); + nextP[7][9] = P[7][9] + P[4][9]*dt + dt*(P[7][6] + P[4][6]*dt); + nextP[7][10] = P[7][10] + P[4][10]*dt; + nextP[7][11] = P[7][11] + P[4][11]*dt; + nextP[7][12] = P[7][12] + P[4][12]*dt; + nextP[7][13] = P[7][13] + P[4][13]*dt; + nextP[7][14] = P[7][14] + P[4][14]*dt; + nextP[7][15] = P[7][15] + P[4][15]*dt; + nextP[7][16] = P[7][16] + P[4][16]*dt; + nextP[7][17] = P[7][17] + P[4][17]*dt; + nextP[7][18] = P[7][18] + P[4][18]*dt; + nextP[7][19] = P[7][19] + P[4][19]*dt; + nextP[7][20] = P[7][20] + P[4][20]*dt; + nextP[8][0] = P[8][0] + P[5][0]*dt + SF[6]*(P[8][1] + P[5][1]*dt) + SPP[7]*(P[8][2] + P[5][2]*dt) + SPP[6]*(P[8][3] + P[5][3]*dt) + SPP[5]*(P[8][10] + P[5][10]*dt) + SPP[4]*(P[8][11] + P[5][11]*dt) + SPP[3]*(P[8][12] + P[5][12]*dt); + nextP[8][1] = P[8][1] + P[5][1]*dt + SF[5]*(P[8][0] + P[5][0]*dt) + SF[4]*(P[8][2] + P[5][2]*dt) + SPP[7]*(P[8][3] + P[5][3]*dt) + SPP[3]*(P[8][11] + P[5][11]*dt) - SPP[4]*(P[8][12] + P[5][12]*dt) - (q0*(P[8][10] + P[5][10]*dt))/2; + nextP[8][2] = P[8][2] + P[5][2]*dt + SF[3]*(P[8][0] + P[5][0]*dt) + SF[5]*(P[8][3] + P[5][3]*dt) + SPP[6]*(P[8][1] + P[5][1]*dt) - SPP[3]*(P[8][10] + P[5][10]*dt) + SPP[5]*(P[8][12] + P[5][12]*dt) - (q0*(P[8][11] + P[5][11]*dt))/2; + nextP[8][3] = P[8][3] + P[5][3]*dt + SF[4]*(P[8][0] + P[5][0]*dt) + SF[3]*(P[8][1] + P[5][1]*dt) + SF[6]*(P[8][2] + P[5][2]*dt) + SPP[4]*(P[8][10] + P[5][10]*dt) - SPP[5]*(P[8][11] + P[5][11]*dt) - (q0*(P[8][12] + P[5][12]*dt))/2; + nextP[8][4] = P[8][4] + P[5][4]*dt + SF[0]*(P[8][1] + P[5][1]*dt) + SF[2]*(P[8][0] + P[5][0]*dt) + SPP[0]*(P[8][2] + P[5][2]*dt) - SPP[2]*(P[8][3] + P[5][3]*dt); + nextP[8][5] = P[8][5] + P[5][5]*dt + SF[1]*(P[8][0] + P[5][0]*dt) + SF[0]*(P[8][2] + P[5][2]*dt) + SF[2]*(P[8][3] + P[5][3]*dt) - SPP[0]*(P[8][1] + P[5][1]*dt); + nextP[8][6] = P[8][6] + P[5][6]*dt + SF[1]*(P[8][1] + P[5][1]*dt) + SF[0]*(P[8][3] + P[5][3]*dt) + SPP[0]*(P[8][0] + P[5][0]*dt) - SPP[1]*(P[8][2] + P[5][2]*dt); + nextP[8][7] = P[8][7] + P[5][7]*dt + dt*(P[8][4] + P[5][4]*dt); + nextP[8][8] = P[8][8] + P[5][8]*dt + dt*(P[8][5] + P[5][5]*dt); + nextP[8][9] = P[8][9] + P[5][9]*dt + dt*(P[8][6] + P[5][6]*dt); + nextP[8][10] = P[8][10] + P[5][10]*dt; + nextP[8][11] = P[8][11] + P[5][11]*dt; + nextP[8][12] = P[8][12] + P[5][12]*dt; + nextP[8][13] = P[8][13] + P[5][13]*dt; + nextP[8][14] = P[8][14] + P[5][14]*dt; + nextP[8][15] = P[8][15] + P[5][15]*dt; + nextP[8][16] = P[8][16] + P[5][16]*dt; + nextP[8][17] = P[8][17] + P[5][17]*dt; + nextP[8][18] = P[8][18] + P[5][18]*dt; + nextP[8][19] = P[8][19] + P[5][19]*dt; + nextP[8][20] = P[8][20] + P[5][20]*dt; + nextP[9][0] = P[9][0] + P[6][0]*dt + SF[6]*(P[9][1] + P[6][1]*dt) + SPP[7]*(P[9][2] + P[6][2]*dt) + SPP[6]*(P[9][3] + P[6][3]*dt) + SPP[5]*(P[9][10] + P[6][10]*dt) + SPP[4]*(P[9][11] + P[6][11]*dt) + SPP[3]*(P[9][12] + P[6][12]*dt); + nextP[9][1] = P[9][1] + P[6][1]*dt + SF[5]*(P[9][0] + P[6][0]*dt) + SF[4]*(P[9][2] + P[6][2]*dt) + SPP[7]*(P[9][3] + P[6][3]*dt) + SPP[3]*(P[9][11] + P[6][11]*dt) - SPP[4]*(P[9][12] + P[6][12]*dt) - (q0*(P[9][10] + P[6][10]*dt))/2; + nextP[9][2] = P[9][2] + P[6][2]*dt + SF[3]*(P[9][0] + P[6][0]*dt) + SF[5]*(P[9][3] + P[6][3]*dt) + SPP[6]*(P[9][1] + P[6][1]*dt) - SPP[3]*(P[9][10] + P[6][10]*dt) + SPP[5]*(P[9][12] + P[6][12]*dt) - (q0*(P[9][11] + P[6][11]*dt))/2; + nextP[9][3] = P[9][3] + P[6][3]*dt + SF[4]*(P[9][0] + P[6][0]*dt) + SF[3]*(P[9][1] + P[6][1]*dt) + SF[6]*(P[9][2] + P[6][2]*dt) + SPP[4]*(P[9][10] + P[6][10]*dt) - SPP[5]*(P[9][11] + P[6][11]*dt) - (q0*(P[9][12] + P[6][12]*dt))/2; + nextP[9][4] = P[9][4] + P[6][4]*dt + SF[0]*(P[9][1] + P[6][1]*dt) + SF[2]*(P[9][0] + P[6][0]*dt) + SPP[0]*(P[9][2] + P[6][2]*dt) - SPP[2]*(P[9][3] + P[6][3]*dt); + nextP[9][5] = P[9][5] + P[6][5]*dt + SF[1]*(P[9][0] + P[6][0]*dt) + SF[0]*(P[9][2] + P[6][2]*dt) + SF[2]*(P[9][3] + P[6][3]*dt) - SPP[0]*(P[9][1] + P[6][1]*dt); + nextP[9][6] = P[9][6] + P[6][6]*dt + SF[1]*(P[9][1] + P[6][1]*dt) + SF[0]*(P[9][3] + P[6][3]*dt) + SPP[0]*(P[9][0] + P[6][0]*dt) - SPP[1]*(P[9][2] + P[6][2]*dt); + nextP[9][7] = P[9][7] + P[6][7]*dt + dt*(P[9][4] + P[6][4]*dt); + nextP[9][8] = P[9][8] + P[6][8]*dt + dt*(P[9][5] + P[6][5]*dt); + nextP[9][9] = P[9][9] + P[6][9]*dt + dt*(P[9][6] + P[6][6]*dt); + nextP[9][10] = P[9][10] + P[6][10]*dt; + nextP[9][11] = P[9][11] + P[6][11]*dt; + nextP[9][12] = P[9][12] + P[6][12]*dt; + nextP[9][13] = P[9][13] + P[6][13]*dt; + nextP[9][14] = P[9][14] + P[6][14]*dt; + nextP[9][15] = P[9][15] + P[6][15]*dt; + nextP[9][16] = P[9][16] + P[6][16]*dt; + nextP[9][17] = P[9][17] + P[6][17]*dt; + nextP[9][18] = P[9][18] + P[6][18]*dt; + nextP[9][19] = P[9][19] + P[6][19]*dt; + nextP[9][20] = P[9][20] + P[6][20]*dt; + nextP[10][0] = P[10][0] + P[10][1]*SF[6] + P[10][2]*SPP[7] + P[10][3]*SPP[6] + P[10][10]*SPP[5] + P[10][11]*SPP[4] + P[10][12]*SPP[3]; + nextP[10][1] = P[10][1] + P[10][0]*SF[5] + P[10][2]*SF[4] + P[10][3]*SPP[7] + P[10][11]*SPP[3] - P[10][12]*SPP[4] - (P[10][10]*q0)/2; + nextP[10][2] = P[10][2] + P[10][0]*SF[3] + P[10][3]*SF[5] + P[10][1]*SPP[6] - P[10][10]*SPP[3] + P[10][12]*SPP[5] - (P[10][11]*q0)/2; + nextP[10][3] = P[10][3] + P[10][0]*SF[4] + P[10][1]*SF[3] + P[10][2]*SF[6] + P[10][10]*SPP[4] - P[10][11]*SPP[5] - (P[10][12]*q0)/2; + nextP[10][4] = P[10][4] + P[10][1]*SF[0] + P[10][0]*SF[2] + P[10][2]*SPP[0] - P[10][3]*SPP[2]; + nextP[10][5] = P[10][5] + P[10][0]*SF[1] + P[10][2]*SF[0] + P[10][3]*SF[2] - P[10][1]*SPP[0]; + nextP[10][6] = P[10][6] + P[10][1]*SF[1] + P[10][3]*SF[0] + P[10][0]*SPP[0] - P[10][2]*SPP[1]; + nextP[10][7] = P[10][7] + P[10][4]*dt; + nextP[10][8] = P[10][8] + P[10][5]*dt; + nextP[10][9] = P[10][9] + P[10][6]*dt; + nextP[10][10] = P[10][10]; + nextP[10][11] = P[10][11]; + nextP[10][12] = P[10][12]; + nextP[10][13] = P[10][13]; + nextP[10][14] = P[10][14]; + nextP[10][15] = P[10][15]; + nextP[10][16] = P[10][16]; + nextP[10][17] = P[10][17]; + nextP[10][18] = P[10][18]; + nextP[10][19] = P[10][19]; + nextP[10][20] = P[10][20]; + nextP[11][0] = P[11][0] + P[11][1]*SF[6] + P[11][2]*SPP[7] + P[11][3]*SPP[6] + P[11][10]*SPP[5] + P[11][11]*SPP[4] + P[11][12]*SPP[3]; + nextP[11][1] = P[11][1] + P[11][0]*SF[5] + P[11][2]*SF[4] + P[11][3]*SPP[7] + P[11][11]*SPP[3] - P[11][12]*SPP[4] - (P[11][10]*q0)/2; + nextP[11][2] = P[11][2] + P[11][0]*SF[3] + P[11][3]*SF[5] + P[11][1]*SPP[6] - P[11][10]*SPP[3] + P[11][12]*SPP[5] - (P[11][11]*q0)/2; + nextP[11][3] = P[11][3] + P[11][0]*SF[4] + P[11][1]*SF[3] + P[11][2]*SF[6] + P[11][10]*SPP[4] - P[11][11]*SPP[5] - (P[11][12]*q0)/2; + nextP[11][4] = P[11][4] + P[11][1]*SF[0] + P[11][0]*SF[2] + P[11][2]*SPP[0] - P[11][3]*SPP[2]; + nextP[11][5] = P[11][5] + P[11][0]*SF[1] + P[11][2]*SF[0] + P[11][3]*SF[2] - P[11][1]*SPP[0]; + nextP[11][6] = P[11][6] + P[11][1]*SF[1] + P[11][3]*SF[0] + P[11][0]*SPP[0] - P[11][2]*SPP[1]; + nextP[11][7] = P[11][7] + P[11][4]*dt; + nextP[11][8] = P[11][8] + P[11][5]*dt; + nextP[11][9] = P[11][9] + P[11][6]*dt; + nextP[11][10] = P[11][10]; + nextP[11][11] = P[11][11]; + nextP[11][12] = P[11][12]; + nextP[11][13] = P[11][13]; + nextP[11][14] = P[11][14]; + nextP[11][15] = P[11][15]; + nextP[11][16] = P[11][16]; + nextP[11][17] = P[11][17]; + nextP[11][18] = P[11][18]; + nextP[11][19] = P[11][19]; + nextP[11][20] = P[11][20]; + nextP[12][0] = P[12][0] + P[12][1]*SF[6] + P[12][2]*SPP[7] + P[12][3]*SPP[6] + P[12][10]*SPP[5] + P[12][11]*SPP[4] + P[12][12]*SPP[3]; + nextP[12][1] = P[12][1] + P[12][0]*SF[5] + P[12][2]*SF[4] + P[12][3]*SPP[7] + P[12][11]*SPP[3] - P[12][12]*SPP[4] - (P[12][10]*q0)/2; + nextP[12][2] = P[12][2] + P[12][0]*SF[3] + P[12][3]*SF[5] + P[12][1]*SPP[6] - P[12][10]*SPP[3] + P[12][12]*SPP[5] - (P[12][11]*q0)/2; + nextP[12][3] = P[12][3] + P[12][0]*SF[4] + P[12][1]*SF[3] + P[12][2]*SF[6] + P[12][10]*SPP[4] - P[12][11]*SPP[5] - (P[12][12]*q0)/2; + nextP[12][4] = P[12][4] + P[12][1]*SF[0] + P[12][0]*SF[2] + P[12][2]*SPP[0] - P[12][3]*SPP[2]; + nextP[12][5] = P[12][5] + P[12][0]*SF[1] + P[12][2]*SF[0] + P[12][3]*SF[2] - P[12][1]*SPP[0]; + nextP[12][6] = P[12][6] + P[12][1]*SF[1] + P[12][3]*SF[0] + P[12][0]*SPP[0] - P[12][2]*SPP[1]; + nextP[12][7] = P[12][7] + P[12][4]*dt; + nextP[12][8] = P[12][8] + P[12][5]*dt; + nextP[12][9] = P[12][9] + P[12][6]*dt; + nextP[12][10] = P[12][10]; + nextP[12][11] = P[12][11]; + nextP[12][12] = P[12][12]; + nextP[12][13] = P[12][13]; + nextP[12][14] = P[12][14]; + nextP[12][15] = P[12][15]; + nextP[12][16] = P[12][16]; + nextP[12][17] = P[12][17]; + nextP[12][18] = P[12][18]; + nextP[12][19] = P[12][19]; + nextP[12][20] = P[12][20]; + nextP[13][0] = P[13][0] + P[13][1]*SF[6] + P[13][2]*SPP[7] + P[13][3]*SPP[6] + P[13][10]*SPP[5] + P[13][11]*SPP[4] + P[13][12]*SPP[3]; + nextP[13][1] = P[13][1] + P[13][0]*SF[5] + P[13][2]*SF[4] + P[13][3]*SPP[7] + P[13][11]*SPP[3] - P[13][12]*SPP[4] - (P[13][10]*q0)/2; + nextP[13][2] = P[13][2] + P[13][0]*SF[3] + P[13][3]*SF[5] + P[13][1]*SPP[6] - P[13][10]*SPP[3] + P[13][12]*SPP[5] - (P[13][11]*q0)/2; + nextP[13][3] = P[13][3] + P[13][0]*SF[4] + P[13][1]*SF[3] + P[13][2]*SF[6] + P[13][10]*SPP[4] - P[13][11]*SPP[5] - (P[13][12]*q0)/2; + nextP[13][4] = P[13][4] + P[13][1]*SF[0] + P[13][0]*SF[2] + P[13][2]*SPP[0] - P[13][3]*SPP[2]; + nextP[13][5] = P[13][5] + P[13][0]*SF[1] + P[13][2]*SF[0] + P[13][3]*SF[2] - P[13][1]*SPP[0]; + nextP[13][6] = P[13][6] + P[13][1]*SF[1] + P[13][3]*SF[0] + P[13][0]*SPP[0] - P[13][2]*SPP[1]; + nextP[13][7] = P[13][7] + P[13][4]*dt; + nextP[13][8] = P[13][8] + P[13][5]*dt; + nextP[13][9] = P[13][9] + P[13][6]*dt; + nextP[13][10] = P[13][10]; + nextP[13][11] = P[13][11]; + nextP[13][12] = P[13][12]; + nextP[13][13] = P[13][13]; + nextP[13][14] = P[13][14]; + nextP[13][15] = P[13][15]; + nextP[13][16] = P[13][16]; + nextP[13][17] = P[13][17]; + nextP[13][18] = P[13][18]; + nextP[13][19] = P[13][19]; + nextP[13][20] = P[13][20]; + nextP[14][0] = P[14][0] + P[14][1]*SF[6] + P[14][2]*SPP[7] + P[14][3]*SPP[6] + P[14][10]*SPP[5] + P[14][11]*SPP[4] + P[14][12]*SPP[3]; + nextP[14][1] = P[14][1] + P[14][0]*SF[5] + P[14][2]*SF[4] + P[14][3]*SPP[7] + P[14][11]*SPP[3] - P[14][12]*SPP[4] - (P[14][10]*q0)/2; + nextP[14][2] = P[14][2] + P[14][0]*SF[3] + P[14][3]*SF[5] + P[14][1]*SPP[6] - P[14][10]*SPP[3] + P[14][12]*SPP[5] - (P[14][11]*q0)/2; + nextP[14][3] = P[14][3] + P[14][0]*SF[4] + P[14][1]*SF[3] + P[14][2]*SF[6] + P[14][10]*SPP[4] - P[14][11]*SPP[5] - (P[14][12]*q0)/2; + nextP[14][4] = P[14][4] + P[14][1]*SF[0] + P[14][0]*SF[2] + P[14][2]*SPP[0] - P[14][3]*SPP[2]; + nextP[14][5] = P[14][5] + P[14][0]*SF[1] + P[14][2]*SF[0] + P[14][3]*SF[2] - P[14][1]*SPP[0]; + nextP[14][6] = P[14][6] + P[14][1]*SF[1] + P[14][3]*SF[0] + P[14][0]*SPP[0] - P[14][2]*SPP[1]; + nextP[14][7] = P[14][7] + P[14][4]*dt; + nextP[14][8] = P[14][8] + P[14][5]*dt; + nextP[14][9] = P[14][9] + P[14][6]*dt; + nextP[14][10] = P[14][10]; + nextP[14][11] = P[14][11]; + nextP[14][12] = P[14][12]; + nextP[14][13] = P[14][13]; + nextP[14][14] = P[14][14]; + nextP[14][15] = P[14][15]; + nextP[14][16] = P[14][16]; + nextP[14][17] = P[14][17]; + nextP[14][18] = P[14][18]; + nextP[14][19] = P[14][19]; + nextP[14][20] = P[14][20]; + nextP[15][0] = P[15][0] + P[15][1]*SF[6] + P[15][2]*SPP[7] + P[15][3]*SPP[6] + P[15][10]*SPP[5] + P[15][11]*SPP[4] + P[15][12]*SPP[3]; + nextP[15][1] = P[15][1] + P[15][0]*SF[5] + P[15][2]*SF[4] + P[15][3]*SPP[7] + P[15][11]*SPP[3] - P[15][12]*SPP[4] - (P[15][10]*q0)/2; + nextP[15][2] = P[15][2] + P[15][0]*SF[3] + P[15][3]*SF[5] + P[15][1]*SPP[6] - P[15][10]*SPP[3] + P[15][12]*SPP[5] - (P[15][11]*q0)/2; + nextP[15][3] = P[15][3] + P[15][0]*SF[4] + P[15][1]*SF[3] + P[15][2]*SF[6] + P[15][10]*SPP[4] - P[15][11]*SPP[5] - (P[15][12]*q0)/2; + nextP[15][4] = P[15][4] + P[15][1]*SF[0] + P[15][0]*SF[2] + P[15][2]*SPP[0] - P[15][3]*SPP[2]; + nextP[15][5] = P[15][5] + P[15][0]*SF[1] + P[15][2]*SF[0] + P[15][3]*SF[2] - P[15][1]*SPP[0]; + nextP[15][6] = P[15][6] + P[15][1]*SF[1] + P[15][3]*SF[0] + P[15][0]*SPP[0] - P[15][2]*SPP[1]; + nextP[15][7] = P[15][7] + P[15][4]*dt; + nextP[15][8] = P[15][8] + P[15][5]*dt; + nextP[15][9] = P[15][9] + P[15][6]*dt; + nextP[15][10] = P[15][10]; + nextP[15][11] = P[15][11]; + nextP[15][12] = P[15][12]; + nextP[15][13] = P[15][13]; + nextP[15][14] = P[15][14]; + nextP[15][15] = P[15][15]; + nextP[15][16] = P[15][16]; + nextP[15][17] = P[15][17]; + nextP[15][18] = P[15][18]; + nextP[15][19] = P[15][19]; + nextP[15][20] = P[15][20]; + nextP[16][0] = P[16][0] + P[16][1]*SF[6] + P[16][2]*SPP[7] + P[16][3]*SPP[6] + P[16][10]*SPP[5] + P[16][11]*SPP[4] + P[16][12]*SPP[3]; + nextP[16][1] = P[16][1] + P[16][0]*SF[5] + P[16][2]*SF[4] + P[16][3]*SPP[7] + P[16][11]*SPP[3] - P[16][12]*SPP[4] - (P[16][10]*q0)/2; + nextP[16][2] = P[16][2] + P[16][0]*SF[3] + P[16][3]*SF[5] + P[16][1]*SPP[6] - P[16][10]*SPP[3] + P[16][12]*SPP[5] - (P[16][11]*q0)/2; + nextP[16][3] = P[16][3] + P[16][0]*SF[4] + P[16][1]*SF[3] + P[16][2]*SF[6] + P[16][10]*SPP[4] - P[16][11]*SPP[5] - (P[16][12]*q0)/2; + nextP[16][4] = P[16][4] + P[16][1]*SF[0] + P[16][0]*SF[2] + P[16][2]*SPP[0] - P[16][3]*SPP[2]; + nextP[16][5] = P[16][5] + P[16][0]*SF[1] + P[16][2]*SF[0] + P[16][3]*SF[2] - P[16][1]*SPP[0]; + nextP[16][6] = P[16][6] + P[16][1]*SF[1] + P[16][3]*SF[0] + P[16][0]*SPP[0] - P[16][2]*SPP[1]; + nextP[16][7] = P[16][7] + P[16][4]*dt; + nextP[16][8] = P[16][8] + P[16][5]*dt; + nextP[16][9] = P[16][9] + P[16][6]*dt; + nextP[16][10] = P[16][10]; + nextP[16][11] = P[16][11]; + nextP[16][12] = P[16][12]; + nextP[16][13] = P[16][13]; + nextP[16][14] = P[16][14]; + nextP[16][15] = P[16][15]; + nextP[16][16] = P[16][16]; + nextP[16][17] = P[16][17]; + nextP[16][18] = P[16][18]; + nextP[16][19] = P[16][19]; + nextP[16][20] = P[16][20]; + nextP[17][0] = P[17][0] + P[17][1]*SF[6] + P[17][2]*SPP[7] + P[17][3]*SPP[6] + P[17][10]*SPP[5] + P[17][11]*SPP[4] + P[17][12]*SPP[3]; + nextP[17][1] = P[17][1] + P[17][0]*SF[5] + P[17][2]*SF[4] + P[17][3]*SPP[7] + P[17][11]*SPP[3] - P[17][12]*SPP[4] - (P[17][10]*q0)/2; + nextP[17][2] = P[17][2] + P[17][0]*SF[3] + P[17][3]*SF[5] + P[17][1]*SPP[6] - P[17][10]*SPP[3] + P[17][12]*SPP[5] - (P[17][11]*q0)/2; + nextP[17][3] = P[17][3] + P[17][0]*SF[4] + P[17][1]*SF[3] + P[17][2]*SF[6] + P[17][10]*SPP[4] - P[17][11]*SPP[5] - (P[17][12]*q0)/2; + nextP[17][4] = P[17][4] + P[17][1]*SF[0] + P[17][0]*SF[2] + P[17][2]*SPP[0] - P[17][3]*SPP[2]; + nextP[17][5] = P[17][5] + P[17][0]*SF[1] + P[17][2]*SF[0] + P[17][3]*SF[2] - P[17][1]*SPP[0]; + nextP[17][6] = P[17][6] + P[17][1]*SF[1] + P[17][3]*SF[0] + P[17][0]*SPP[0] - P[17][2]*SPP[1]; + nextP[17][7] = P[17][7] + P[17][4]*dt; + nextP[17][8] = P[17][8] + P[17][5]*dt; + nextP[17][9] = P[17][9] + P[17][6]*dt; + nextP[17][10] = P[17][10]; + nextP[17][11] = P[17][11]; + nextP[17][12] = P[17][12]; + nextP[17][13] = P[17][13]; + nextP[17][14] = P[17][14]; + nextP[17][15] = P[17][15]; + nextP[17][16] = P[17][16]; + nextP[17][17] = P[17][17]; + nextP[17][18] = P[17][18]; + nextP[17][19] = P[17][19]; + nextP[17][20] = P[17][20]; + nextP[18][0] = P[18][0] + P[18][1]*SF[6] + P[18][2]*SPP[7] + P[18][3]*SPP[6] + P[18][10]*SPP[5] + P[18][11]*SPP[4] + P[18][12]*SPP[3]; + nextP[18][1] = P[18][1] + P[18][0]*SF[5] + P[18][2]*SF[4] + P[18][3]*SPP[7] + P[18][11]*SPP[3] - P[18][12]*SPP[4] - (P[18][10]*q0)/2; + nextP[18][2] = P[18][2] + P[18][0]*SF[3] + P[18][3]*SF[5] + P[18][1]*SPP[6] - P[18][10]*SPP[3] + P[18][12]*SPP[5] - (P[18][11]*q0)/2; + nextP[18][3] = P[18][3] + P[18][0]*SF[4] + P[18][1]*SF[3] + P[18][2]*SF[6] + P[18][10]*SPP[4] - P[18][11]*SPP[5] - (P[18][12]*q0)/2; + nextP[18][4] = P[18][4] + P[18][1]*SF[0] + P[18][0]*SF[2] + P[18][2]*SPP[0] - P[18][3]*SPP[2]; + nextP[18][5] = P[18][5] + P[18][0]*SF[1] + P[18][2]*SF[0] + P[18][3]*SF[2] - P[18][1]*SPP[0]; + nextP[18][6] = P[18][6] + P[18][1]*SF[1] + P[18][3]*SF[0] + P[18][0]*SPP[0] - P[18][2]*SPP[1]; + nextP[18][7] = P[18][7] + P[18][4]*dt; + nextP[18][8] = P[18][8] + P[18][5]*dt; + nextP[18][9] = P[18][9] + P[18][6]*dt; + nextP[18][10] = P[18][10]; + nextP[18][11] = P[18][11]; + nextP[18][12] = P[18][12]; + nextP[18][13] = P[18][13]; + nextP[18][14] = P[18][14]; + nextP[18][15] = P[18][15]; + nextP[18][16] = P[18][16]; + nextP[18][17] = P[18][17]; + nextP[18][18] = P[18][18]; + nextP[18][19] = P[18][19]; + nextP[18][20] = P[18][20]; + nextP[19][0] = P[19][0] + P[19][1]*SF[6] + P[19][2]*SPP[7] + P[19][3]*SPP[6] + P[19][10]*SPP[5] + P[19][11]*SPP[4] + P[19][12]*SPP[3]; + nextP[19][1] = P[19][1] + P[19][0]*SF[5] + P[19][2]*SF[4] + P[19][3]*SPP[7] + P[19][11]*SPP[3] - P[19][12]*SPP[4] - (P[19][10]*q0)/2; + nextP[19][2] = P[19][2] + P[19][0]*SF[3] + P[19][3]*SF[5] + P[19][1]*SPP[6] - P[19][10]*SPP[3] + P[19][12]*SPP[5] - (P[19][11]*q0)/2; + nextP[19][3] = P[19][3] + P[19][0]*SF[4] + P[19][1]*SF[3] + P[19][2]*SF[6] + P[19][10]*SPP[4] - P[19][11]*SPP[5] - (P[19][12]*q0)/2; + nextP[19][4] = P[19][4] + P[19][1]*SF[0] + P[19][0]*SF[2] + P[19][2]*SPP[0] - P[19][3]*SPP[2]; + nextP[19][5] = P[19][5] + P[19][0]*SF[1] + P[19][2]*SF[0] + P[19][3]*SF[2] - P[19][1]*SPP[0]; + nextP[19][6] = P[19][6] + P[19][1]*SF[1] + P[19][3]*SF[0] + P[19][0]*SPP[0] - P[19][2]*SPP[1]; + nextP[19][7] = P[19][7] + P[19][4]*dt; + nextP[19][8] = P[19][8] + P[19][5]*dt; + nextP[19][9] = P[19][9] + P[19][6]*dt; + nextP[19][10] = P[19][10]; + nextP[19][11] = P[19][11]; + nextP[19][12] = P[19][12]; + nextP[19][13] = P[19][13]; + nextP[19][14] = P[19][14]; + nextP[19][15] = P[19][15]; + nextP[19][16] = P[19][16]; + nextP[19][17] = P[19][17]; + nextP[19][18] = P[19][18]; + nextP[19][19] = P[19][19]; + nextP[19][20] = P[19][20]; + nextP[20][0] = P[20][0] + P[20][1]*SF[6] + P[20][2]*SPP[7] + P[20][3]*SPP[6] + P[20][10]*SPP[5] + P[20][11]*SPP[4] + P[20][12]*SPP[3]; + nextP[20][1] = P[20][1] + P[20][0]*SF[5] + P[20][2]*SF[4] + P[20][3]*SPP[7] + P[20][11]*SPP[3] - P[20][12]*SPP[4] - (P[20][10]*q0)/2; + nextP[20][2] = P[20][2] + P[20][0]*SF[3] + P[20][3]*SF[5] + P[20][1]*SPP[6] - P[20][10]*SPP[3] + P[20][12]*SPP[5] - (P[20][11]*q0)/2; + nextP[20][3] = P[20][3] + P[20][0]*SF[4] + P[20][1]*SF[3] + P[20][2]*SF[6] + P[20][10]*SPP[4] - P[20][11]*SPP[5] - (P[20][12]*q0)/2; + nextP[20][4] = P[20][4] + P[20][1]*SF[0] + P[20][0]*SF[2] + P[20][2]*SPP[0] - P[20][3]*SPP[2]; + nextP[20][5] = P[20][5] + P[20][0]*SF[1] + P[20][2]*SF[0] + P[20][3]*SF[2] - P[20][1]*SPP[0]; + nextP[20][6] = P[20][6] + P[20][1]*SF[1] + P[20][3]*SF[0] + P[20][0]*SPP[0] - P[20][2]*SPP[1]; + nextP[20][7] = P[20][7] + P[20][4]*dt; + nextP[20][8] = P[20][8] + P[20][5]*dt; + nextP[20][9] = P[20][9] + P[20][6]*dt; + nextP[20][10] = P[20][10]; + nextP[20][11] = P[20][11]; + nextP[20][12] = P[20][12]; + nextP[20][13] = P[20][13]; + nextP[20][14] = P[20][14]; + nextP[20][15] = P[20][15]; + nextP[20][16] = P[20][16]; + nextP[20][17] = P[20][17]; + nextP[20][18] = P[20][18]; + nextP[20][19] = P[20][19]; + nextP[20][20] = P[20][20]; + + for (unsigned i = 0; i < n_states; i++) + { + nextP[i][i] = nextP[i][i] + processNoise[i]; + } + + // If on ground or no magnetometer fitted, inhibit magnetometer bias updates by + // setting the coresponding covariance terms to zero. + if (onGround || !useCompass) + { + zeroRows(nextP,15,20); + zeroCols(nextP,15,20); + } + + // If on ground or not using airspeed sensing, inhibit wind velocity + // covariance growth. + if (onGround || !useAirspeed) + { + zeroRows(nextP,13,14); + zeroCols(nextP,13,14); + } + + // If the total position variance exceds 1E6 (1000m), then stop covariance + // growth by setting the predicted to the previous values + // This prevent an ill conditioned matrix from occurring for long periods + // without GPS + if ((P[7][7] + P[8][8]) > 1E6f) + { + for (uint8_t i=7; i<=8; i++) + { + for (unsigned j = 0; j < n_states; j++) + { + nextP[i][j] = P[i][j]; + nextP[j][i] = P[j][i]; + } + } + } + + if (onGround || staticMode) { + // copy the portion of the variances we want to + // propagate + for (unsigned i = 0; i < 14; i++) { + P[i][i] = nextP[i][i]; + + // force symmetry for observable states + // force zero for non-observable states + for (unsigned i = 1; i < n_states; i++) + { + for (uint8_t j = 0; j < i; j++) + { + if ((i > 12) || (j > 12)) { + P[i][j] = 0.0f; + } else { + P[i][j] = 0.5f * (nextP[i][j] + nextP[j][i]); + } + P[j][i] = P[i][j]; + } + } + } + + } else { + + // Copy covariance + for (unsigned i = 0; i < n_states; i++) { + P[i][i] = nextP[i][i]; + } + + // force symmetry for observable states + for (unsigned i = 1; i < n_states; i++) + { + for (uint8_t j = 0; j < i; j++) + { + P[i][j] = 0.5f * (nextP[i][j] + nextP[j][i]); + P[j][i] = P[i][j]; + } + } + + } + + ConstrainVariances(); +} + +void AttPosEKF::FuseVelposNED() +{ + +// declare variables used by fault isolation logic + uint32_t gpsRetryTime = 30000; // time in msec before GPS fusion will be retried following innovation consistency failure + uint32_t gpsRetryTimeNoTAS = 5000; // retry time if no TAS measurement available + uint32_t hgtRetryTime = 5000; // height measurement retry time + uint32_t horizRetryTime; + +// declare variables used to check measurement errors + float velInnov[3] = {0.0f,0.0f,0.0f}; + float posInnov[2] = {0.0f,0.0f}; + float hgtInnov = 0.0f; + +// declare variables used to control access to arrays + bool fuseData[6] = {false,false,false,false,false,false}; + uint8_t stateIndex; + uint8_t obsIndex; + uint8_t indexLimit; + +// declare variables used by state and covariance update calculations + float velErr; + float posErr; + float R_OBS[6]; + float observation[6]; + float SK; + float quatMag; + +// Perform sequential fusion of GPS measurements. This assumes that the +// errors in the different velocity and position components are +// uncorrelated which is not true, however in the absence of covariance +// data from the GPS receiver it is the only assumption we can make +// so we might as well take advantage of the computational efficiencies +// associated with sequential fusion + if (fuseVelData || fusePosData || fuseHgtData) + { + // set the GPS data timeout depending on whether airspeed data is present + if (useAirspeed) horizRetryTime = gpsRetryTime; + else horizRetryTime = gpsRetryTimeNoTAS; + + // Form the observation vector + for (uint8_t i=0; i<=2; i++) observation[i] = velNED[i]; + for (uint8_t i=3; i<=4; i++) observation[i] = posNE[i-3]; + observation[5] = -(hgtMea); + + // Estimate the GPS Velocity, GPS horiz position and height measurement variances. + velErr = 0.2f*accNavMag; // additional error in GPS velocities caused by manoeuvring + posErr = 0.2f*accNavMag; // additional error in GPS position caused by manoeuvring + R_OBS[0] = 0.04f + sq(velErr); + R_OBS[1] = R_OBS[0]; + R_OBS[2] = 0.08f + sq(velErr); + R_OBS[3] = R_OBS[2]; + R_OBS[4] = 4.0f + sq(posErr); + R_OBS[5] = 4.0f; + + // Set innovation variances to zero default + for (uint8_t i = 0; i<=5; i++) + { + varInnovVelPos[i] = 0.0f; + } + // calculate innovations and check GPS data validity using an innovation consistency check + if (fuseVelData) + { + // test velocity measurements + uint8_t imax = 2; + if (fusionModeGPS == 1) imax = 1; + for (uint8_t i = 0; i<=imax; i++) + { + velInnov[i] = statesAtVelTime[i+4] - velNED[i]; + stateIndex = 4 + i; + varInnovVelPos[i] = P[stateIndex][stateIndex] + R_OBS[i]; + } + // apply a 5-sigma threshold + current_ekf_state.velHealth = (sq(velInnov[0]) + sq(velInnov[1]) + sq(velInnov[2])) < 25.0f * (varInnovVelPos[0] + varInnovVelPos[1] + varInnovVelPos[2]); + current_ekf_state.velTimeout = (millis() - current_ekf_state.velFailTime) > horizRetryTime; + if (current_ekf_state.velHealth || current_ekf_state.velTimeout) + { + current_ekf_state.velHealth = true; + current_ekf_state.velFailTime = millis(); + } + else + { + current_ekf_state.velHealth = false; + } + } + if (fusePosData) + { + // test horizontal position measurements + posInnov[0] = statesAtPosTime[7] - posNE[0]; + posInnov[1] = statesAtPosTime[8] - posNE[1]; + varInnovVelPos[3] = P[7][7] + R_OBS[3]; + varInnovVelPos[4] = P[8][8] + R_OBS[4]; + // apply a 10-sigma threshold + current_ekf_state.posHealth = (sq(posInnov[0]) + sq(posInnov[1])) < 100.0f*(varInnovVelPos[3] + varInnovVelPos[4]); + current_ekf_state.posTimeout = (millis() - current_ekf_state.posFailTime) > horizRetryTime; + if (current_ekf_state.posHealth || current_ekf_state.posTimeout) + { + current_ekf_state.posHealth = true; + current_ekf_state.posFailTime = millis(); + } + else + { + current_ekf_state.posHealth = false; + } + } + // test height measurements + if (fuseHgtData) + { + hgtInnov = statesAtHgtTime[9] + hgtMea; + varInnovVelPos[5] = P[9][9] + R_OBS[5]; + // apply a 10-sigma threshold + current_ekf_state.hgtHealth = sq(hgtInnov) < 100.0f*varInnovVelPos[5]; + current_ekf_state.hgtTimeout = (millis() - current_ekf_state.hgtFailTime) > hgtRetryTime; + if (current_ekf_state.hgtHealth || current_ekf_state.hgtTimeout) + { + current_ekf_state.hgtHealth = true; + current_ekf_state.hgtFailTime = millis(); + } + else + { + current_ekf_state.hgtHealth = false; + } + } + // Set range for sequential fusion of velocity and position measurements depending + // on which data is available and its health + if (fuseVelData && fusionModeGPS == 0 && current_ekf_state.velHealth) + { + fuseData[0] = true; + fuseData[1] = true; + fuseData[2] = true; + } + if (fuseVelData && fusionModeGPS == 1 && current_ekf_state.velHealth) + { + fuseData[0] = true; + fuseData[1] = true; + } + if (fusePosData && fusionModeGPS <= 2 && current_ekf_state.posHealth) + { + fuseData[3] = true; + fuseData[4] = true; + } + if (fuseHgtData && current_ekf_state.hgtHealth) + { + fuseData[5] = true; + } + // Limit range of states modified when on ground + if(!onGround) + { + indexLimit = 20; + } + else + { + indexLimit = 12; + } + // Fuse measurements sequentially + for (obsIndex=0; obsIndex<=5; obsIndex++) + { + if (fuseData[obsIndex]) + { + stateIndex = 4 + obsIndex; + // Calculate the measurement innovation, using states from a + // different time coordinate if fusing height data + if (obsIndex >= 0 && obsIndex <= 2) + { + innovVelPos[obsIndex] = statesAtVelTime[stateIndex] - observation[obsIndex]; + } + else if (obsIndex == 3 || obsIndex == 4) + { + innovVelPos[obsIndex] = statesAtPosTime[stateIndex] - observation[obsIndex]; + } + else if (obsIndex == 5) + { + innovVelPos[obsIndex] = statesAtHgtTime[stateIndex] - observation[obsIndex]; + } + // Calculate the Kalman Gain + // Calculate innovation variances - also used for data logging + varInnovVelPos[obsIndex] = P[stateIndex][stateIndex] + R_OBS[obsIndex]; + SK = 1.0/varInnovVelPos[obsIndex]; + for (uint8_t i= 0; i<=indexLimit; i++) + { + Kfusion[i] = P[i][stateIndex]*SK; + } + // Calculate state corrections and re-normalise the quaternions + for (uint8_t i = 0; i<=indexLimit; i++) + { + states[i] = states[i] - Kfusion[i] * innovVelPos[obsIndex]; + } + quatMag = sqrt(states[0]*states[0] + states[1]*states[1] + states[2]*states[2] + states[3]*states[3]); + if (quatMag > 1e-12f) // divide by 0 protection + { + for (uint8_t i = 0; i<=3; i++) + { + states[i] = states[i] / quatMag; + } + } + // Update the covariance - take advantage of direct observation of a + // single state at index = stateIndex to reduce computations + // Optimised implementation of standard equation P = (I - K*H)*P; + for (uint8_t i= 0; i<=indexLimit; i++) + { + for (uint8_t j= 0; j<=indexLimit; j++) + { + KHP[i][j] = Kfusion[i] * P[stateIndex][j]; + } + } + for (uint8_t i= 0; i<=indexLimit; i++) + { + for (uint8_t j= 0; j<=indexLimit; j++) + { + P[i][j] = P[i][j] - KHP[i][j]; + } + } + } + } + } + + ForceSymmetry(); + ConstrainVariances(); + + //printf("velh: %s, posh: %s, hgth: %s\n", ((velHealth) ? "OK" : "FAIL"), ((posHealth) ? "OK" : "FAIL"), ((hgtHealth) ? "OK" : "FAIL")); +} + +void AttPosEKF::FuseMagnetometer() +{ + uint8_t obsIndex; + uint8_t indexLimit; + float DCM[3][3] = + { + {1.0f,0.0f,0.0f} , + {0.0f,1.0f,0.0f} , + {0.0f,0.0f,1.0f} + }; + float MagPred[3] = {0.0f,0.0f,0.0f}; + float SK_MX[6]; + float SK_MY[5]; + float SK_MZ[6]; + float SH_MAG[9] = {0.0f,0.0f,0.0f,0.0f,0.0f,0.0f,0.0f,0.0f,0.0f}; + +// Perform sequential fusion of Magnetometer measurements. +// This assumes that the errors in the different components are +// uncorrelated which is not true, however in the absence of covariance +// data fit is the only assumption we can make +// so we might as well take advantage of the computational efficiencies +// associated with sequential fusion + if (useCompass && (fuseMagData || obsIndex == 1 || obsIndex == 2)) + { + // Limit range of states modified when on ground + if(!onGround) + { + indexLimit = 20; + } + else + { + indexLimit = 12; + } + + static float q0 = 0.0f; + static float q1 = 0.0f; + static float q2 = 0.0f; + static float q3 = 1.0f; + static float magN = 0.4f; + static float magE = 0.0f; + static float magD = 0.3f; + + static float R_MAG = 0.0025f; + + float H_MAG[21] = {0.0f,0.0f,0.0f,0.0f,0.0f,0.0f,0.0f,0.0f,0.0f,0.0f,0.0f,0.0f,0.0f,0.0f,0.0f,0.0f,0.0f,0.0f,0.0f,0.0f,0.0f}; + + // Sequential fusion of XYZ components to spread processing load across + // three prediction time steps. + + // Calculate observation jacobians and Kalman gains + if (fuseMagData) + { + static float magXbias = 0.0f; + static float magYbias = 0.0f; + static float magZbias = 0.0f; + + // Copy required states to local variable names + q0 = statesAtMagMeasTime[0]; + q1 = statesAtMagMeasTime[1]; + q2 = statesAtMagMeasTime[2]; + q3 = statesAtMagMeasTime[3]; + magN = statesAtMagMeasTime[15]; + magE = statesAtMagMeasTime[16]; + magD = statesAtMagMeasTime[17]; + magXbias = statesAtMagMeasTime[18]; + magYbias = statesAtMagMeasTime[19]; + magZbias = statesAtMagMeasTime[20]; + + // rotate predicted earth components into body axes and calculate + // predicted measurments + DCM[0][0] = q0*q0 + q1*q1 - q2*q2 - q3*q3; + DCM[0][1] = 2*(q1*q2 + q0*q3); + DCM[0][2] = 2*(q1*q3-q0*q2); + DCM[1][0] = 2*(q1*q2 - q0*q3); + DCM[1][1] = q0*q0 - q1*q1 + q2*q2 - q3*q3; + DCM[1][2] = 2*(q2*q3 + q0*q1); + DCM[2][0] = 2*(q1*q3 + q0*q2); + DCM[2][1] = 2*(q2*q3 - q0*q1); + DCM[2][2] = q0*q0 - q1*q1 - q2*q2 + q3*q3; + MagPred[0] = DCM[0][0]*magN + DCM[0][1]*magE + DCM[0][2]*magD + magXbias; + MagPred[1] = DCM[1][0]*magN + DCM[1][1]*magE + DCM[1][2]*magD + magYbias; + MagPred[2] = DCM[2][0]*magN + DCM[2][1]*magE + DCM[2][2]*magD + magZbias; + + // scale magnetometer observation error with total angular rate + R_MAG = 0.0025f + sq(0.05f*dAngIMU.length()/dtIMU); + + // Calculate observation jacobians + SH_MAG[0] = 2*magD*q3 + 2*magE*q2 + 2*magN*q1; + SH_MAG[1] = 2*magD*q0 - 2*magE*q1 + 2*magN*q2; + SH_MAG[2] = 2*magD*q1 + 2*magE*q0 - 2*magN*q3; + SH_MAG[3] = sq(q3); + SH_MAG[4] = sq(q2); + SH_MAG[5] = sq(q1); + SH_MAG[6] = sq(q0); + SH_MAG[7] = 2*magN*q0; + SH_MAG[8] = 2*magE*q3; + + for (uint8_t i=0; i<=20; i++) H_MAG[i] = 0; + H_MAG[0] = SH_MAG[7] + SH_MAG[8] - 2*magD*q2; + H_MAG[1] = SH_MAG[0]; + H_MAG[2] = 2*magE*q1 - 2*magD*q0 - 2*magN*q2; + H_MAG[3] = SH_MAG[2]; + H_MAG[15] = SH_MAG[5] - SH_MAG[4] - SH_MAG[3] + SH_MAG[6]; + H_MAG[16] = 2*q0*q3 + 2*q1*q2; + H_MAG[17] = 2*q1*q3 - 2*q0*q2; + H_MAG[18] = 1.0f; + + // Calculate Kalman gain + SK_MX[0] = 1/(P[18][18] + R_MAG + P[1][18]*SH_MAG[0] + P[3][18]*SH_MAG[2] - P[15][18]*(SH_MAG[3] + SH_MAG[4] - SH_MAG[5] - SH_MAG[6]) - (2*magD*q0 - 2*magE*q1 + 2*magN*q2)*(P[18][2] + P[1][2]*SH_MAG[0] + P[3][2]*SH_MAG[2] - P[15][2]*(SH_MAG[3] + SH_MAG[4] - SH_MAG[5] - SH_MAG[6]) + P[16][2]*(2*q0*q3 + 2*q1*q2) - P[17][2]*(2*q0*q2 - 2*q1*q3) - P[2][2]*(2*magD*q0 - 2*magE*q1 + 2*magN*q2) + P[0][2]*(SH_MAG[7] + SH_MAG[8] - 2*magD*q2)) + (SH_MAG[7] + SH_MAG[8] - 2*magD*q2)*(P[18][0] + P[1][0]*SH_MAG[0] + P[3][0]*SH_MAG[2] - P[15][0]*(SH_MAG[3] + SH_MAG[4] - SH_MAG[5] - SH_MAG[6]) + P[16][0]*(2*q0*q3 + 2*q1*q2) - P[17][0]*(2*q0*q2 - 2*q1*q3) - P[2][0]*(2*magD*q0 - 2*magE*q1 + 2*magN*q2) + P[0][0]*(SH_MAG[7] + SH_MAG[8] - 2*magD*q2)) + SH_MAG[0]*(P[18][1] + P[1][1]*SH_MAG[0] + P[3][1]*SH_MAG[2] - P[15][1]*(SH_MAG[3] + SH_MAG[4] - SH_MAG[5] - SH_MAG[6]) + P[16][1]*(2*q0*q3 + 2*q1*q2) - P[17][1]*(2*q0*q2 - 2*q1*q3) - P[2][1]*(2*magD*q0 - 2*magE*q1 + 2*magN*q2) + P[0][1]*(SH_MAG[7] + SH_MAG[8] - 2*magD*q2)) + SH_MAG[2]*(P[18][3] + P[1][3]*SH_MAG[0] + P[3][3]*SH_MAG[2] - P[15][3]*(SH_MAG[3] + SH_MAG[4] - SH_MAG[5] - SH_MAG[6]) + P[16][3]*(2*q0*q3 + 2*q1*q2) - P[17][3]*(2*q0*q2 - 2*q1*q3) - P[2][3]*(2*magD*q0 - 2*magE*q1 + 2*magN*q2) + P[0][3]*(SH_MAG[7] + SH_MAG[8] - 2*magD*q2)) - (SH_MAG[3] + SH_MAG[4] - SH_MAG[5] - SH_MAG[6])*(P[18][15] + P[1][15]*SH_MAG[0] + P[3][15]*SH_MAG[2] - P[15][15]*(SH_MAG[3] + SH_MAG[4] - SH_MAG[5] - SH_MAG[6]) + P[16][15]*(2*q0*q3 + 2*q1*q2) - P[17][15]*(2*q0*q2 - 2*q1*q3) - P[2][15]*(2*magD*q0 - 2*magE*q1 + 2*magN*q2) + P[0][15]*(SH_MAG[7] + SH_MAG[8] - 2*magD*q2)) + P[16][18]*(2*q0*q3 + 2*q1*q2) - P[17][18]*(2*q0*q2 - 2*q1*q3) - P[2][18]*(2*magD*q0 - 2*magE*q1 + 2*magN*q2) + (2*q0*q3 + 2*q1*q2)*(P[18][16] + P[1][16]*SH_MAG[0] + P[3][16]*SH_MAG[2] - P[15][16]*(SH_MAG[3] + SH_MAG[4] - SH_MAG[5] - SH_MAG[6]) + P[16][16]*(2*q0*q3 + 2*q1*q2) - P[17][16]*(2*q0*q2 - 2*q1*q3) - P[2][16]*(2*magD*q0 - 2*magE*q1 + 2*magN*q2) + P[0][16]*(SH_MAG[7] + SH_MAG[8] - 2*magD*q2)) - (2*q0*q2 - 2*q1*q3)*(P[18][17] + P[1][17]*SH_MAG[0] + P[3][17]*SH_MAG[2] - P[15][17]*(SH_MAG[3] + SH_MAG[4] - SH_MAG[5] - SH_MAG[6]) + P[16][17]*(2*q0*q3 + 2*q1*q2) - P[17][17]*(2*q0*q2 - 2*q1*q3) - P[2][17]*(2*magD*q0 - 2*magE*q1 + 2*magN*q2) + P[0][17]*(SH_MAG[7] + SH_MAG[8] - 2*magD*q2)) + P[0][18]*(SH_MAG[7] + SH_MAG[8] - 2*magD*q2)); + SK_MX[1] = SH_MAG[3] + SH_MAG[4] - SH_MAG[5] - SH_MAG[6]; + SK_MX[2] = 2*magD*q0 - 2*magE*q1 + 2*magN*q2; + SK_MX[3] = SH_MAG[7] + SH_MAG[8] - 2*magD*q2; + SK_MX[4] = 2*q0*q2 - 2*q1*q3; + SK_MX[5] = 2*q0*q3 + 2*q1*q2; + Kfusion[0] = SK_MX[0]*(P[0][18] + P[0][1]*SH_MAG[0] + P[0][3]*SH_MAG[2] + P[0][0]*SK_MX[3] - P[0][2]*SK_MX[2] - P[0][15]*SK_MX[1] + P[0][16]*SK_MX[5] - P[0][17]*SK_MX[4]); + Kfusion[1] = SK_MX[0]*(P[1][18] + P[1][1]*SH_MAG[0] + P[1][3]*SH_MAG[2] + P[1][0]*SK_MX[3] - P[1][2]*SK_MX[2] - P[1][15]*SK_MX[1] + P[1][16]*SK_MX[5] - P[1][17]*SK_MX[4]); + Kfusion[2] = SK_MX[0]*(P[2][18] + P[2][1]*SH_MAG[0] + P[2][3]*SH_MAG[2] + P[2][0]*SK_MX[3] - P[2][2]*SK_MX[2] - P[2][15]*SK_MX[1] + P[2][16]*SK_MX[5] - P[2][17]*SK_MX[4]); + Kfusion[3] = SK_MX[0]*(P[3][18] + P[3][1]*SH_MAG[0] + P[3][3]*SH_MAG[2] + P[3][0]*SK_MX[3] - P[3][2]*SK_MX[2] - P[3][15]*SK_MX[1] + P[3][16]*SK_MX[5] - P[3][17]*SK_MX[4]); + Kfusion[4] = SK_MX[0]*(P[4][18] + P[4][1]*SH_MAG[0] + P[4][3]*SH_MAG[2] + P[4][0]*SK_MX[3] - P[4][2]*SK_MX[2] - P[4][15]*SK_MX[1] + P[4][16]*SK_MX[5] - P[4][17]*SK_MX[4]); + Kfusion[5] = SK_MX[0]*(P[5][18] + P[5][1]*SH_MAG[0] + P[5][3]*SH_MAG[2] + P[5][0]*SK_MX[3] - P[5][2]*SK_MX[2] - P[5][15]*SK_MX[1] + P[5][16]*SK_MX[5] - P[5][17]*SK_MX[4]); + Kfusion[6] = SK_MX[0]*(P[6][18] + P[6][1]*SH_MAG[0] + P[6][3]*SH_MAG[2] + P[6][0]*SK_MX[3] - P[6][2]*SK_MX[2] - P[6][15]*SK_MX[1] + P[6][16]*SK_MX[5] - P[6][17]*SK_MX[4]); + Kfusion[7] = SK_MX[0]*(P[7][18] + P[7][1]*SH_MAG[0] + P[7][3]*SH_MAG[2] + P[7][0]*SK_MX[3] - P[7][2]*SK_MX[2] - P[7][15]*SK_MX[1] + P[7][16]*SK_MX[5] - P[7][17]*SK_MX[4]); + Kfusion[8] = SK_MX[0]*(P[8][18] + P[8][1]*SH_MAG[0] + P[8][3]*SH_MAG[2] + P[8][0]*SK_MX[3] - P[8][2]*SK_MX[2] - P[8][15]*SK_MX[1] + P[8][16]*SK_MX[5] - P[8][17]*SK_MX[4]); + Kfusion[9] = SK_MX[0]*(P[9][18] + P[9][1]*SH_MAG[0] + P[9][3]*SH_MAG[2] + P[9][0]*SK_MX[3] - P[9][2]*SK_MX[2] - P[9][15]*SK_MX[1] + P[9][16]*SK_MX[5] - P[9][17]*SK_MX[4]); + Kfusion[10] = SK_MX[0]*(P[10][18] + P[10][1]*SH_MAG[0] + P[10][3]*SH_MAG[2] + P[10][0]*SK_MX[3] - P[10][2]*SK_MX[2] - P[10][15]*SK_MX[1] + P[10][16]*SK_MX[5] - P[10][17]*SK_MX[4]); + Kfusion[11] = SK_MX[0]*(P[11][18] + P[11][1]*SH_MAG[0] + P[11][3]*SH_MAG[2] + P[11][0]*SK_MX[3] - P[11][2]*SK_MX[2] - P[11][15]*SK_MX[1] + P[11][16]*SK_MX[5] - P[11][17]*SK_MX[4]); + Kfusion[12] = SK_MX[0]*(P[12][18] + P[12][1]*SH_MAG[0] + P[12][3]*SH_MAG[2] + P[12][0]*SK_MX[3] - P[12][2]*SK_MX[2] - P[12][15]*SK_MX[1] + P[12][16]*SK_MX[5] - P[12][17]*SK_MX[4]); + Kfusion[13] = SK_MX[0]*(P[13][18] + P[13][1]*SH_MAG[0] + P[13][3]*SH_MAG[2] + P[13][0]*SK_MX[3] - P[13][2]*SK_MX[2] - P[13][15]*SK_MX[1] + P[13][16]*SK_MX[5] - P[13][17]*SK_MX[4]); + Kfusion[14] = SK_MX[0]*(P[14][18] + P[14][1]*SH_MAG[0] + P[14][3]*SH_MAG[2] + P[14][0]*SK_MX[3] - P[14][2]*SK_MX[2] - P[14][15]*SK_MX[1] + P[14][16]*SK_MX[5] - P[14][17]*SK_MX[4]); + Kfusion[15] = SK_MX[0]*(P[15][18] + P[15][1]*SH_MAG[0] + P[15][3]*SH_MAG[2] + P[15][0]*SK_MX[3] - P[15][2]*SK_MX[2] - P[15][15]*SK_MX[1] + P[15][16]*SK_MX[5] - P[15][17]*SK_MX[4]); + Kfusion[16] = SK_MX[0]*(P[16][18] + P[16][1]*SH_MAG[0] + P[16][3]*SH_MAG[2] + P[16][0]*SK_MX[3] - P[16][2]*SK_MX[2] - P[16][15]*SK_MX[1] + P[16][16]*SK_MX[5] - P[16][17]*SK_MX[4]); + Kfusion[17] = SK_MX[0]*(P[17][18] + P[17][1]*SH_MAG[0] + P[17][3]*SH_MAG[2] + P[17][0]*SK_MX[3] - P[17][2]*SK_MX[2] - P[17][15]*SK_MX[1] + P[17][16]*SK_MX[5] - P[17][17]*SK_MX[4]); + Kfusion[18] = SK_MX[0]*(P[18][18] + P[18][1]*SH_MAG[0] + P[18][3]*SH_MAG[2] + P[18][0]*SK_MX[3] - P[18][2]*SK_MX[2] - P[18][15]*SK_MX[1] + P[18][16]*SK_MX[5] - P[18][17]*SK_MX[4]); + Kfusion[19] = SK_MX[0]*(P[19][18] + P[19][1]*SH_MAG[0] + P[19][3]*SH_MAG[2] + P[19][0]*SK_MX[3] - P[19][2]*SK_MX[2] - P[19][15]*SK_MX[1] + P[19][16]*SK_MX[5] - P[19][17]*SK_MX[4]); + Kfusion[20] = SK_MX[0]*(P[20][18] + P[20][1]*SH_MAG[0] + P[20][3]*SH_MAG[2] + P[20][0]*SK_MX[3] - P[20][2]*SK_MX[2] - P[20][15]*SK_MX[1] + P[20][16]*SK_MX[5] - P[20][17]*SK_MX[4]); + varInnovMag[0] = 1.0f/SK_MX[0]; + innovMag[0] = MagPred[0] - magData.x; + + // reset the observation index to 0 (we start by fusing the X + // measurement) + obsIndex = 0; + } + else if (obsIndex == 1) // we are now fusing the Y measurement + { + // Calculate observation jacobians + for (unsigned int i=0; i<n_states; i++) H_MAG[i] = 0; + H_MAG[0] = SH_MAG[2]; + H_MAG[1] = SH_MAG[1]; + H_MAG[2] = SH_MAG[0]; + H_MAG[3] = 2*magD*q2 - SH_MAG[8] - SH_MAG[7]; + H_MAG[15] = 2*q1*q2 - 2*q0*q3; + H_MAG[16] = SH_MAG[4] - SH_MAG[3] - SH_MAG[5] + SH_MAG[6]; + H_MAG[17] = 2*q0*q1 + 2*q2*q3; + H_MAG[19] = 1; + + // Calculate Kalman gain + SK_MY[0] = 1/(P[19][19] + R_MAG + P[0][19]*SH_MAG[2] + P[1][19]*SH_MAG[1] + P[2][19]*SH_MAG[0] - P[16][19]*(SH_MAG[3] - SH_MAG[4] + SH_MAG[5] - SH_MAG[6]) - (2*q0*q3 - 2*q1*q2)*(P[19][15] + P[0][15]*SH_MAG[2] + P[1][15]*SH_MAG[1] + P[2][15]*SH_MAG[0] - P[16][15]*(SH_MAG[3] - SH_MAG[4] + SH_MAG[5] - SH_MAG[6]) - P[15][15]*(2*q0*q3 - 2*q1*q2) + P[17][15]*(2*q0*q1 + 2*q2*q3) - P[3][15]*(SH_MAG[7] + SH_MAG[8] - 2*magD*q2)) + (2*q0*q1 + 2*q2*q3)*(P[19][17] + P[0][17]*SH_MAG[2] + P[1][17]*SH_MAG[1] + P[2][17]*SH_MAG[0] - P[16][17]*(SH_MAG[3] - SH_MAG[4] + SH_MAG[5] - SH_MAG[6]) - P[15][17]*(2*q0*q3 - 2*q1*q2) + P[17][17]*(2*q0*q1 + 2*q2*q3) - P[3][17]*(SH_MAG[7] + SH_MAG[8] - 2*magD*q2)) - (SH_MAG[7] + SH_MAG[8] - 2*magD*q2)*(P[19][3] + P[0][3]*SH_MAG[2] + P[1][3]*SH_MAG[1] + P[2][3]*SH_MAG[0] - P[16][3]*(SH_MAG[3] - SH_MAG[4] + SH_MAG[5] - SH_MAG[6]) - P[15][3]*(2*q0*q3 - 2*q1*q2) + P[17][3]*(2*q0*q1 + 2*q2*q3) - P[3][3]*(SH_MAG[7] + SH_MAG[8] - 2*magD*q2)) - P[15][19]*(2*q0*q3 - 2*q1*q2) + P[17][19]*(2*q0*q1 + 2*q2*q3) + SH_MAG[2]*(P[19][0] + P[0][0]*SH_MAG[2] + P[1][0]*SH_MAG[1] + P[2][0]*SH_MAG[0] - P[16][0]*(SH_MAG[3] - SH_MAG[4] + SH_MAG[5] - SH_MAG[6]) - P[15][0]*(2*q0*q3 - 2*q1*q2) + P[17][0]*(2*q0*q1 + 2*q2*q3) - P[3][0]*(SH_MAG[7] + SH_MAG[8] - 2*magD*q2)) + SH_MAG[1]*(P[19][1] + P[0][1]*SH_MAG[2] + P[1][1]*SH_MAG[1] + P[2][1]*SH_MAG[0] - P[16][1]*(SH_MAG[3] - SH_MAG[4] + SH_MAG[5] - SH_MAG[6]) - P[15][1]*(2*q0*q3 - 2*q1*q2) + P[17][1]*(2*q0*q1 + 2*q2*q3) - P[3][1]*(SH_MAG[7] + SH_MAG[8] - 2*magD*q2)) + SH_MAG[0]*(P[19][2] + P[0][2]*SH_MAG[2] + P[1][2]*SH_MAG[1] + P[2][2]*SH_MAG[0] - P[16][2]*(SH_MAG[3] - SH_MAG[4] + SH_MAG[5] - SH_MAG[6]) - P[15][2]*(2*q0*q3 - 2*q1*q2) + P[17][2]*(2*q0*q1 + 2*q2*q3) - P[3][2]*(SH_MAG[7] + SH_MAG[8] - 2*magD*q2)) - (SH_MAG[3] - SH_MAG[4] + SH_MAG[5] - SH_MAG[6])*(P[19][16] + P[0][16]*SH_MAG[2] + P[1][16]*SH_MAG[1] + P[2][16]*SH_MAG[0] - P[16][16]*(SH_MAG[3] - SH_MAG[4] + SH_MAG[5] - SH_MAG[6]) - P[15][16]*(2*q0*q3 - 2*q1*q2) + P[17][16]*(2*q0*q1 + 2*q2*q3) - P[3][16]*(SH_MAG[7] + SH_MAG[8] - 2*magD*q2)) - P[3][19]*(SH_MAG[7] + SH_MAG[8] - 2*magD*q2)); + SK_MY[1] = SH_MAG[3] - SH_MAG[4] + SH_MAG[5] - SH_MAG[6]; + SK_MY[2] = SH_MAG[7] + SH_MAG[8] - 2*magD*q2; + SK_MY[3] = 2*q0*q3 - 2*q1*q2; + SK_MY[4] = 2*q0*q1 + 2*q2*q3; + Kfusion[0] = SK_MY[0]*(P[0][19] + P[0][0]*SH_MAG[2] + P[0][1]*SH_MAG[1] + P[0][2]*SH_MAG[0] - P[0][3]*SK_MY[2] - P[0][16]*SK_MY[1] - P[0][15]*SK_MY[3] + P[0][17]*SK_MY[4]); + Kfusion[1] = SK_MY[0]*(P[1][19] + P[1][0]*SH_MAG[2] + P[1][1]*SH_MAG[1] + P[1][2]*SH_MAG[0] - P[1][3]*SK_MY[2] - P[1][16]*SK_MY[1] - P[1][15]*SK_MY[3] + P[1][17]*SK_MY[4]); + Kfusion[2] = SK_MY[0]*(P[2][19] + P[2][0]*SH_MAG[2] + P[2][1]*SH_MAG[1] + P[2][2]*SH_MAG[0] - P[2][3]*SK_MY[2] - P[2][16]*SK_MY[1] - P[2][15]*SK_MY[3] + P[2][17]*SK_MY[4]); + Kfusion[3] = SK_MY[0]*(P[3][19] + P[3][0]*SH_MAG[2] + P[3][1]*SH_MAG[1] + P[3][2]*SH_MAG[0] - P[3][3]*SK_MY[2] - P[3][16]*SK_MY[1] - P[3][15]*SK_MY[3] + P[3][17]*SK_MY[4]); + Kfusion[4] = SK_MY[0]*(P[4][19] + P[4][0]*SH_MAG[2] + P[4][1]*SH_MAG[1] + P[4][2]*SH_MAG[0] - P[4][3]*SK_MY[2] - P[4][16]*SK_MY[1] - P[4][15]*SK_MY[3] + P[4][17]*SK_MY[4]); + Kfusion[5] = SK_MY[0]*(P[5][19] + P[5][0]*SH_MAG[2] + P[5][1]*SH_MAG[1] + P[5][2]*SH_MAG[0] - P[5][3]*SK_MY[2] - P[5][16]*SK_MY[1] - P[5][15]*SK_MY[3] + P[5][17]*SK_MY[4]); + Kfusion[6] = SK_MY[0]*(P[6][19] + P[6][0]*SH_MAG[2] + P[6][1]*SH_MAG[1] + P[6][2]*SH_MAG[0] - P[6][3]*SK_MY[2] - P[6][16]*SK_MY[1] - P[6][15]*SK_MY[3] + P[6][17]*SK_MY[4]); + Kfusion[7] = SK_MY[0]*(P[7][19] + P[7][0]*SH_MAG[2] + P[7][1]*SH_MAG[1] + P[7][2]*SH_MAG[0] - P[7][3]*SK_MY[2] - P[7][16]*SK_MY[1] - P[7][15]*SK_MY[3] + P[7][17]*SK_MY[4]); + Kfusion[8] = SK_MY[0]*(P[8][19] + P[8][0]*SH_MAG[2] + P[8][1]*SH_MAG[1] + P[8][2]*SH_MAG[0] - P[8][3]*SK_MY[2] - P[8][16]*SK_MY[1] - P[8][15]*SK_MY[3] + P[8][17]*SK_MY[4]); + Kfusion[9] = SK_MY[0]*(P[9][19] + P[9][0]*SH_MAG[2] + P[9][1]*SH_MAG[1] + P[9][2]*SH_MAG[0] - P[9][3]*SK_MY[2] - P[9][16]*SK_MY[1] - P[9][15]*SK_MY[3] + P[9][17]*SK_MY[4]); + Kfusion[10] = SK_MY[0]*(P[10][19] + P[10][0]*SH_MAG[2] + P[10][1]*SH_MAG[1] + P[10][2]*SH_MAG[0] - P[10][3]*SK_MY[2] - P[10][16]*SK_MY[1] - P[10][15]*SK_MY[3] + P[10][17]*SK_MY[4]); + Kfusion[11] = SK_MY[0]*(P[11][19] + P[11][0]*SH_MAG[2] + P[11][1]*SH_MAG[1] + P[11][2]*SH_MAG[0] - P[11][3]*SK_MY[2] - P[11][16]*SK_MY[1] - P[11][15]*SK_MY[3] + P[11][17]*SK_MY[4]); + Kfusion[12] = SK_MY[0]*(P[12][19] + P[12][0]*SH_MAG[2] + P[12][1]*SH_MAG[1] + P[12][2]*SH_MAG[0] - P[12][3]*SK_MY[2] - P[12][16]*SK_MY[1] - P[12][15]*SK_MY[3] + P[12][17]*SK_MY[4]); + Kfusion[13] = SK_MY[0]*(P[13][19] + P[13][0]*SH_MAG[2] + P[13][1]*SH_MAG[1] + P[13][2]*SH_MAG[0] - P[13][3]*SK_MY[2] - P[13][16]*SK_MY[1] - P[13][15]*SK_MY[3] + P[13][17]*SK_MY[4]); + Kfusion[14] = SK_MY[0]*(P[14][19] + P[14][0]*SH_MAG[2] + P[14][1]*SH_MAG[1] + P[14][2]*SH_MAG[0] - P[14][3]*SK_MY[2] - P[14][16]*SK_MY[1] - P[14][15]*SK_MY[3] + P[14][17]*SK_MY[4]); + Kfusion[15] = SK_MY[0]*(P[15][19] + P[15][0]*SH_MAG[2] + P[15][1]*SH_MAG[1] + P[15][2]*SH_MAG[0] - P[15][3]*SK_MY[2] - P[15][16]*SK_MY[1] - P[15][15]*SK_MY[3] + P[15][17]*SK_MY[4]); + Kfusion[16] = SK_MY[0]*(P[16][19] + P[16][0]*SH_MAG[2] + P[16][1]*SH_MAG[1] + P[16][2]*SH_MAG[0] - P[16][3]*SK_MY[2] - P[16][16]*SK_MY[1] - P[16][15]*SK_MY[3] + P[16][17]*SK_MY[4]); + Kfusion[17] = SK_MY[0]*(P[17][19] + P[17][0]*SH_MAG[2] + P[17][1]*SH_MAG[1] + P[17][2]*SH_MAG[0] - P[17][3]*SK_MY[2] - P[17][16]*SK_MY[1] - P[17][15]*SK_MY[3] + P[17][17]*SK_MY[4]); + Kfusion[18] = SK_MY[0]*(P[18][19] + P[18][0]*SH_MAG[2] + P[18][1]*SH_MAG[1] + P[18][2]*SH_MAG[0] - P[18][3]*SK_MY[2] - P[18][16]*SK_MY[1] - P[18][15]*SK_MY[3] + P[18][17]*SK_MY[4]); + Kfusion[19] = SK_MY[0]*(P[19][19] + P[19][0]*SH_MAG[2] + P[19][1]*SH_MAG[1] + P[19][2]*SH_MAG[0] - P[19][3]*SK_MY[2] - P[19][16]*SK_MY[1] - P[19][15]*SK_MY[3] + P[19][17]*SK_MY[4]); + Kfusion[20] = SK_MY[0]*(P[20][19] + P[20][0]*SH_MAG[2] + P[20][1]*SH_MAG[1] + P[20][2]*SH_MAG[0] - P[20][3]*SK_MY[2] - P[20][16]*SK_MY[1] - P[20][15]*SK_MY[3] + P[20][17]*SK_MY[4]); + varInnovMag[1] = 1.0f/SK_MY[0]; + innovMag[1] = MagPred[1] - magData.y; + } + else if (obsIndex == 2) // we are now fusing the Z measurement + { + // Calculate observation jacobians + for (uint8_t i=0; i<=20; i++) H_MAG[i] = 0; + H_MAG[0] = SH_MAG[1]; + H_MAG[1] = 2*magN*q3 - 2*magE*q0 - 2*magD*q1; + H_MAG[2] = SH_MAG[7] + SH_MAG[8] - 2*magD*q2; + H_MAG[3] = SH_MAG[0]; + H_MAG[15] = 2*q0*q2 + 2*q1*q3; + H_MAG[16] = 2*q2*q3 - 2*q0*q1; + H_MAG[17] = SH_MAG[3] - SH_MAG[4] - SH_MAG[5] + SH_MAG[6]; + H_MAG[20] = 1; + + // Calculate Kalman gain + SK_MZ[0] = 1/(P[20][20] + R_MAG + P[0][20]*SH_MAG[1] + P[3][20]*SH_MAG[0] + P[17][20]*(SH_MAG[3] - SH_MAG[4] - SH_MAG[5] + SH_MAG[6]) - (2*magD*q1 + 2*magE*q0 - 2*magN*q3)*(P[20][1] + P[0][1]*SH_MAG[1] + P[3][1]*SH_MAG[0] + P[17][1]*(SH_MAG[3] - SH_MAG[4] - SH_MAG[5] + SH_MAG[6]) + P[15][1]*(2*q0*q2 + 2*q1*q3) - P[16][1]*(2*q0*q1 - 2*q2*q3) - P[1][1]*(2*magD*q1 + 2*magE*q0 - 2*magN*q3) + P[2][1]*(SH_MAG[7] + SH_MAG[8] - 2*magD*q2)) + (SH_MAG[7] + SH_MAG[8] - 2*magD*q2)*(P[20][2] + P[0][2]*SH_MAG[1] + P[3][2]*SH_MAG[0] + P[17][2]*(SH_MAG[3] - SH_MAG[4] - SH_MAG[5] + SH_MAG[6]) + P[15][2]*(2*q0*q2 + 2*q1*q3) - P[16][2]*(2*q0*q1 - 2*q2*q3) - P[1][2]*(2*magD*q1 + 2*magE*q0 - 2*magN*q3) + P[2][2]*(SH_MAG[7] + SH_MAG[8] - 2*magD*q2)) + SH_MAG[1]*(P[20][0] + P[0][0]*SH_MAG[1] + P[3][0]*SH_MAG[0] + P[17][0]*(SH_MAG[3] - SH_MAG[4] - SH_MAG[5] + SH_MAG[6]) + P[15][0]*(2*q0*q2 + 2*q1*q3) - P[16][0]*(2*q0*q1 - 2*q2*q3) - P[1][0]*(2*magD*q1 + 2*magE*q0 - 2*magN*q3) + P[2][0]*(SH_MAG[7] + SH_MAG[8] - 2*magD*q2)) + SH_MAG[0]*(P[20][3] + P[0][3]*SH_MAG[1] + P[3][3]*SH_MAG[0] + P[17][3]*(SH_MAG[3] - SH_MAG[4] - SH_MAG[5] + SH_MAG[6]) + P[15][3]*(2*q0*q2 + 2*q1*q3) - P[16][3]*(2*q0*q1 - 2*q2*q3) - P[1][3]*(2*magD*q1 + 2*magE*q0 - 2*magN*q3) + P[2][3]*(SH_MAG[7] + SH_MAG[8] - 2*magD*q2)) + (SH_MAG[3] - SH_MAG[4] - SH_MAG[5] + SH_MAG[6])*(P[20][17] + P[0][17]*SH_MAG[1] + P[3][17]*SH_MAG[0] + P[17][17]*(SH_MAG[3] - SH_MAG[4] - SH_MAG[5] + SH_MAG[6]) + P[15][17]*(2*q0*q2 + 2*q1*q3) - P[16][17]*(2*q0*q1 - 2*q2*q3) - P[1][17]*(2*magD*q1 + 2*magE*q0 - 2*magN*q3) + P[2][17]*(SH_MAG[7] + SH_MAG[8] - 2*magD*q2)) + P[15][20]*(2*q0*q2 + 2*q1*q3) - P[16][20]*(2*q0*q1 - 2*q2*q3) - P[1][20]*(2*magD*q1 + 2*magE*q0 - 2*magN*q3) + (2*q0*q2 + 2*q1*q3)*(P[20][15] + P[0][15]*SH_MAG[1] + P[3][15]*SH_MAG[0] + P[17][15]*(SH_MAG[3] - SH_MAG[4] - SH_MAG[5] + SH_MAG[6]) + P[15][15]*(2*q0*q2 + 2*q1*q3) - P[16][15]*(2*q0*q1 - 2*q2*q3) - P[1][15]*(2*magD*q1 + 2*magE*q0 - 2*magN*q3) + P[2][15]*(SH_MAG[7] + SH_MAG[8] - 2*magD*q2)) - (2*q0*q1 - 2*q2*q3)*(P[20][16] + P[0][16]*SH_MAG[1] + P[3][16]*SH_MAG[0] + P[17][16]*(SH_MAG[3] - SH_MAG[4] - SH_MAG[5] + SH_MAG[6]) + P[15][16]*(2*q0*q2 + 2*q1*q3) - P[16][16]*(2*q0*q1 - 2*q2*q3) - P[1][16]*(2*magD*q1 + 2*magE*q0 - 2*magN*q3) + P[2][16]*(SH_MAG[7] + SH_MAG[8] - 2*magD*q2)) + P[2][20]*(SH_MAG[7] + SH_MAG[8] - 2*magD*q2)); + SK_MZ[1] = SH_MAG[3] - SH_MAG[4] - SH_MAG[5] + SH_MAG[6]; + SK_MZ[2] = 2*magD*q1 + 2*magE*q0 - 2*magN*q3; + SK_MZ[3] = SH_MAG[7] + SH_MAG[8] - 2*magD*q2; + SK_MZ[4] = 2*q0*q1 - 2*q2*q3; + SK_MZ[5] = 2*q0*q2 + 2*q1*q3; + Kfusion[0] = SK_MZ[0]*(P[0][20] + P[0][0]*SH_MAG[1] + P[0][3]*SH_MAG[0] - P[0][1]*SK_MZ[2] + P[0][2]*SK_MZ[3] + P[0][17]*SK_MZ[1] + P[0][15]*SK_MZ[5] - P[0][16]*SK_MZ[4]); + Kfusion[1] = SK_MZ[0]*(P[1][20] + P[1][0]*SH_MAG[1] + P[1][3]*SH_MAG[0] - P[1][1]*SK_MZ[2] + P[1][2]*SK_MZ[3] + P[1][17]*SK_MZ[1] + P[1][15]*SK_MZ[5] - P[1][16]*SK_MZ[4]); + Kfusion[2] = SK_MZ[0]*(P[2][20] + P[2][0]*SH_MAG[1] + P[2][3]*SH_MAG[0] - P[2][1]*SK_MZ[2] + P[2][2]*SK_MZ[3] + P[2][17]*SK_MZ[1] + P[2][15]*SK_MZ[5] - P[2][16]*SK_MZ[4]); + Kfusion[3] = SK_MZ[0]*(P[3][20] + P[3][0]*SH_MAG[1] + P[3][3]*SH_MAG[0] - P[3][1]*SK_MZ[2] + P[3][2]*SK_MZ[3] + P[3][17]*SK_MZ[1] + P[3][15]*SK_MZ[5] - P[3][16]*SK_MZ[4]); + Kfusion[4] = SK_MZ[0]*(P[4][20] + P[4][0]*SH_MAG[1] + P[4][3]*SH_MAG[0] - P[4][1]*SK_MZ[2] + P[4][2]*SK_MZ[3] + P[4][17]*SK_MZ[1] + P[4][15]*SK_MZ[5] - P[4][16]*SK_MZ[4]); + Kfusion[5] = SK_MZ[0]*(P[5][20] + P[5][0]*SH_MAG[1] + P[5][3]*SH_MAG[0] - P[5][1]*SK_MZ[2] + P[5][2]*SK_MZ[3] + P[5][17]*SK_MZ[1] + P[5][15]*SK_MZ[5] - P[5][16]*SK_MZ[4]); + Kfusion[6] = SK_MZ[0]*(P[6][20] + P[6][0]*SH_MAG[1] + P[6][3]*SH_MAG[0] - P[6][1]*SK_MZ[2] + P[6][2]*SK_MZ[3] + P[6][17]*SK_MZ[1] + P[6][15]*SK_MZ[5] - P[6][16]*SK_MZ[4]); + Kfusion[7] = SK_MZ[0]*(P[7][20] + P[7][0]*SH_MAG[1] + P[7][3]*SH_MAG[0] - P[7][1]*SK_MZ[2] + P[7][2]*SK_MZ[3] + P[7][17]*SK_MZ[1] + P[7][15]*SK_MZ[5] - P[7][16]*SK_MZ[4]); + Kfusion[8] = SK_MZ[0]*(P[8][20] + P[8][0]*SH_MAG[1] + P[8][3]*SH_MAG[0] - P[8][1]*SK_MZ[2] + P[8][2]*SK_MZ[3] + P[8][17]*SK_MZ[1] + P[8][15]*SK_MZ[5] - P[8][16]*SK_MZ[4]); + Kfusion[9] = SK_MZ[0]*(P[9][20] + P[9][0]*SH_MAG[1] + P[9][3]*SH_MAG[0] - P[9][1]*SK_MZ[2] + P[9][2]*SK_MZ[3] + P[9][17]*SK_MZ[1] + P[9][15]*SK_MZ[5] - P[9][16]*SK_MZ[4]); + Kfusion[10] = SK_MZ[0]*(P[10][20] + P[10][0]*SH_MAG[1] + P[10][3]*SH_MAG[0] - P[10][1]*SK_MZ[2] + P[10][2]*SK_MZ[3] + P[10][17]*SK_MZ[1] + P[10][15]*SK_MZ[5] - P[10][16]*SK_MZ[4]); + Kfusion[11] = SK_MZ[0]*(P[11][20] + P[11][0]*SH_MAG[1] + P[11][3]*SH_MAG[0] - P[11][1]*SK_MZ[2] + P[11][2]*SK_MZ[3] + P[11][17]*SK_MZ[1] + P[11][15]*SK_MZ[5] - P[11][16]*SK_MZ[4]); + Kfusion[12] = SK_MZ[0]*(P[12][20] + P[12][0]*SH_MAG[1] + P[12][3]*SH_MAG[0] - P[12][1]*SK_MZ[2] + P[12][2]*SK_MZ[3] + P[12][17]*SK_MZ[1] + P[12][15]*SK_MZ[5] - P[12][16]*SK_MZ[4]); + Kfusion[13] = SK_MZ[0]*(P[13][20] + P[13][0]*SH_MAG[1] + P[13][3]*SH_MAG[0] - P[13][1]*SK_MZ[2] + P[13][2]*SK_MZ[3] + P[13][17]*SK_MZ[1] + P[13][15]*SK_MZ[5] - P[13][16]*SK_MZ[4]); + Kfusion[14] = SK_MZ[0]*(P[14][20] + P[14][0]*SH_MAG[1] + P[14][3]*SH_MAG[0] - P[14][1]*SK_MZ[2] + P[14][2]*SK_MZ[3] + P[14][17]*SK_MZ[1] + P[14][15]*SK_MZ[5] - P[14][16]*SK_MZ[4]); + Kfusion[15] = SK_MZ[0]*(P[15][20] + P[15][0]*SH_MAG[1] + P[15][3]*SH_MAG[0] - P[15][1]*SK_MZ[2] + P[15][2]*SK_MZ[3] + P[15][17]*SK_MZ[1] + P[15][15]*SK_MZ[5] - P[15][16]*SK_MZ[4]); + Kfusion[16] = SK_MZ[0]*(P[16][20] + P[16][0]*SH_MAG[1] + P[16][3]*SH_MAG[0] - P[16][1]*SK_MZ[2] + P[16][2]*SK_MZ[3] + P[16][17]*SK_MZ[1] + P[16][15]*SK_MZ[5] - P[16][16]*SK_MZ[4]); + Kfusion[17] = SK_MZ[0]*(P[17][20] + P[17][0]*SH_MAG[1] + P[17][3]*SH_MAG[0] - P[17][1]*SK_MZ[2] + P[17][2]*SK_MZ[3] + P[17][17]*SK_MZ[1] + P[17][15]*SK_MZ[5] - P[17][16]*SK_MZ[4]); + Kfusion[18] = SK_MZ[0]*(P[18][20] + P[18][0]*SH_MAG[1] + P[18][3]*SH_MAG[0] - P[18][1]*SK_MZ[2] + P[18][2]*SK_MZ[3] + P[18][17]*SK_MZ[1] + P[18][15]*SK_MZ[5] - P[18][16]*SK_MZ[4]); + Kfusion[19] = SK_MZ[0]*(P[19][20] + P[19][0]*SH_MAG[1] + P[19][3]*SH_MAG[0] - P[19][1]*SK_MZ[2] + P[19][2]*SK_MZ[3] + P[19][17]*SK_MZ[1] + P[19][15]*SK_MZ[5] - P[19][16]*SK_MZ[4]); + Kfusion[20] = SK_MZ[0]*(P[20][20] + P[20][0]*SH_MAG[1] + P[20][3]*SH_MAG[0] - P[20][1]*SK_MZ[2] + P[20][2]*SK_MZ[3] + P[20][17]*SK_MZ[1] + P[20][15]*SK_MZ[5] - P[20][16]*SK_MZ[4]); + varInnovMag[2] = 1.0f/SK_MZ[0]; + innovMag[2] = MagPred[2] - magData.z; + + } + + // Check the innovation for consistency and don't fuse if > 5Sigma + if ((innovMag[obsIndex]*innovMag[obsIndex]/varInnovMag[obsIndex]) < 25.0) + { + // correct the state vector + for (uint8_t j= 0; j<=indexLimit; j++) + { + states[j] = states[j] - Kfusion[j] * innovMag[obsIndex]; + } + // normalise the quaternion states + float quatMag = sqrt(states[0]*states[0] + states[1]*states[1] + states[2]*states[2] + states[3]*states[3]); + if (quatMag > 1e-12) + { + for (uint8_t j= 0; j<=3; j++) + { + float quatMagInv = 1.0f/quatMag; + states[j] = states[j] * quatMagInv; + } + } + // correct the covariance P = (I - K*H)*P + // take advantage of the empty columns in KH to reduce the + // number of operations + for (uint8_t i = 0; i<=indexLimit; i++) + { + for (uint8_t j = 0; j<=3; j++) + { + KH[i][j] = Kfusion[i] * H_MAG[j]; + } + for (uint8_t j = 4; j<=17; j++) KH[i][j] = 0.0f; + if (!onGround) + { + for (uint8_t j = 15; j<=20; j++) + { + KH[i][j] = Kfusion[i] * H_MAG[j]; + } + } + else + { + for (uint8_t j = 15; j<=20; j++) + { + KH[i][j] = 0.0f; + } + } + } + for (uint8_t i = 0; i<=indexLimit; i++) + { + for (uint8_t j = 0; j<=indexLimit; j++) + { + KHP[i][j] = 0.0f; + for (uint8_t k = 0; k<=3; k++) + { + KHP[i][j] = KHP[i][j] + KH[i][k] * P[k][j]; + } + if (!onGround) + { + for (uint8_t k = 15; k<=20; k++) + { + KHP[i][j] = KHP[i][j] + KH[i][k] * P[k][j]; + } + } + } + } + } + for (uint8_t i = 0; i<=indexLimit; i++) + { + for (uint8_t j = 0; j<=indexLimit; j++) + { + P[i][j] = P[i][j] - KHP[i][j]; + } + } + } + obsIndex = obsIndex + 1; + + ForceSymmetry(); + ConstrainVariances(); +} + +void AttPosEKF::FuseAirspeed() +{ + float vn; + float ve; + float vd; + float vwn; + float vwe; + const float R_TAS = 2.0f; + float SH_TAS[3]; + float Kfusion[21]; + float VtasPred; + + // Copy required states to local variable names + vn = statesAtVtasMeasTime[4]; + ve = statesAtVtasMeasTime[5]; + vd = statesAtVtasMeasTime[6]; + vwn = statesAtVtasMeasTime[13]; + vwe = statesAtVtasMeasTime[14]; + + // Need to check that it is flying before fusing airspeed data + // Calculate the predicted airspeed + VtasPred = sqrtf((ve - vwe)*(ve - vwe) + (vn - vwn)*(vn - vwn) + vd*vd); + // Perform fusion of True Airspeed measurement + if (useAirspeed && fuseVtasData && (VtasPred > 1.0f) && (VtasMeas > 8.0f)) + { + // Calculate observation jacobians + SH_TAS[0] = 1/(sqrt(sq(ve - vwe) + sq(vn - vwn) + sq(vd))); + SH_TAS[1] = (SH_TAS[0]*(2.0f*ve - 2*vwe))/2.0f; + SH_TAS[2] = (SH_TAS[0]*(2.0f*vn - 2*vwn))/2.0f; + + float H_TAS[21]; + for (uint8_t i=0; i<=20; i++) H_TAS[i] = 0.0f; + H_TAS[4] = SH_TAS[2]; + H_TAS[5] = SH_TAS[1]; + H_TAS[6] = vd*SH_TAS[0]; + H_TAS[13] = -SH_TAS[2]; + H_TAS[14] = -SH_TAS[1]; + + // Calculate Kalman gains + float SK_TAS = 1.0f/(R_TAS + SH_TAS[2]*(P[4][4]*SH_TAS[2] + P[5][4]*SH_TAS[1] - P[13][4]*SH_TAS[2] - P[14][4]*SH_TAS[1] + P[6][4]*vd*SH_TAS[0]) + SH_TAS[1]*(P[4][5]*SH_TAS[2] + P[5][5]*SH_TAS[1] - P[13][5]*SH_TAS[2] - P[14][5]*SH_TAS[1] + P[6][5]*vd*SH_TAS[0]) - SH_TAS[2]*(P[4][13]*SH_TAS[2] + P[5][13]*SH_TAS[1] - P[13][13]*SH_TAS[2] - P[14][13]*SH_TAS[1] + P[6][13]*vd*SH_TAS[0]) - SH_TAS[1]*(P[4][14]*SH_TAS[2] + P[5][14]*SH_TAS[1] - P[13][14]*SH_TAS[2] - P[14][14]*SH_TAS[1] + P[6][14]*vd*SH_TAS[0]) + vd*SH_TAS[0]*(P[4][6]*SH_TAS[2] + P[5][6]*SH_TAS[1] - P[13][6]*SH_TAS[2] - P[14][6]*SH_TAS[1] + P[6][6]*vd*SH_TAS[0])); + Kfusion[0] = SK_TAS*(P[0][4]*SH_TAS[2] - P[0][13]*SH_TAS[2] + P[0][5]*SH_TAS[1] - P[0][14]*SH_TAS[1] + P[0][6]*vd*SH_TAS[0]); + Kfusion[1] = SK_TAS*(P[1][4]*SH_TAS[2] - P[1][13]*SH_TAS[2] + P[1][5]*SH_TAS[1] - P[1][14]*SH_TAS[1] + P[1][6]*vd*SH_TAS[0]); + Kfusion[2] = SK_TAS*(P[2][4]*SH_TAS[2] - P[2][13]*SH_TAS[2] + P[2][5]*SH_TAS[1] - P[2][14]*SH_TAS[1] + P[2][6]*vd*SH_TAS[0]); + Kfusion[3] = SK_TAS*(P[3][4]*SH_TAS[2] - P[3][13]*SH_TAS[2] + P[3][5]*SH_TAS[1] - P[3][14]*SH_TAS[1] + P[3][6]*vd*SH_TAS[0]); + Kfusion[4] = SK_TAS*(P[4][4]*SH_TAS[2] - P[4][13]*SH_TAS[2] + P[4][5]*SH_TAS[1] - P[4][14]*SH_TAS[1] + P[4][6]*vd*SH_TAS[0]); + Kfusion[5] = SK_TAS*(P[5][4]*SH_TAS[2] - P[5][13]*SH_TAS[2] + P[5][5]*SH_TAS[1] - P[5][14]*SH_TAS[1] + P[5][6]*vd*SH_TAS[0]); + Kfusion[6] = SK_TAS*(P[6][4]*SH_TAS[2] - P[6][13]*SH_TAS[2] + P[6][5]*SH_TAS[1] - P[6][14]*SH_TAS[1] + P[6][6]*vd*SH_TAS[0]); + Kfusion[7] = SK_TAS*(P[7][4]*SH_TAS[2] - P[7][13]*SH_TAS[2] + P[7][5]*SH_TAS[1] - P[7][14]*SH_TAS[1] + P[7][6]*vd*SH_TAS[0]); + Kfusion[8] = SK_TAS*(P[8][4]*SH_TAS[2] - P[8][13]*SH_TAS[2] + P[8][5]*SH_TAS[1] - P[8][14]*SH_TAS[1] + P[8][6]*vd*SH_TAS[0]); + Kfusion[9] = SK_TAS*(P[9][4]*SH_TAS[2] - P[9][13]*SH_TAS[2] + P[9][5]*SH_TAS[1] - P[9][14]*SH_TAS[1] + P[9][6]*vd*SH_TAS[0]); + Kfusion[10] = SK_TAS*(P[10][4]*SH_TAS[2] - P[10][13]*SH_TAS[2] + P[10][5]*SH_TAS[1] - P[10][14]*SH_TAS[1] + P[10][6]*vd*SH_TAS[0]); + Kfusion[11] = SK_TAS*(P[11][4]*SH_TAS[2] - P[11][13]*SH_TAS[2] + P[11][5]*SH_TAS[1] - P[11][14]*SH_TAS[1] + P[11][6]*vd*SH_TAS[0]); + Kfusion[12] = SK_TAS*(P[12][4]*SH_TAS[2] - P[12][13]*SH_TAS[2] + P[12][5]*SH_TAS[1] - P[12][14]*SH_TAS[1] + P[12][6]*vd*SH_TAS[0]); + Kfusion[13] = SK_TAS*(P[13][4]*SH_TAS[2] - P[13][13]*SH_TAS[2] + P[13][5]*SH_TAS[1] - P[13][14]*SH_TAS[1] + P[13][6]*vd*SH_TAS[0]); + Kfusion[14] = SK_TAS*(P[14][4]*SH_TAS[2] - P[14][13]*SH_TAS[2] + P[14][5]*SH_TAS[1] - P[14][14]*SH_TAS[1] + P[14][6]*vd*SH_TAS[0]); + Kfusion[15] = SK_TAS*(P[15][4]*SH_TAS[2] - P[15][13]*SH_TAS[2] + P[15][5]*SH_TAS[1] - P[15][14]*SH_TAS[1] + P[15][6]*vd*SH_TAS[0]); + Kfusion[16] = SK_TAS*(P[16][4]*SH_TAS[2] - P[16][13]*SH_TAS[2] + P[16][5]*SH_TAS[1] - P[16][14]*SH_TAS[1] + P[16][6]*vd*SH_TAS[0]); + Kfusion[17] = SK_TAS*(P[17][4]*SH_TAS[2] - P[17][13]*SH_TAS[2] + P[17][5]*SH_TAS[1] - P[17][14]*SH_TAS[1] + P[17][6]*vd*SH_TAS[0]); + Kfusion[18] = SK_TAS*(P[18][4]*SH_TAS[2] - P[18][13]*SH_TAS[2] + P[18][5]*SH_TAS[1] - P[18][14]*SH_TAS[1] + P[18][6]*vd*SH_TAS[0]); + Kfusion[19] = SK_TAS*(P[19][4]*SH_TAS[2] - P[19][13]*SH_TAS[2] + P[19][5]*SH_TAS[1] - P[19][14]*SH_TAS[1] + P[19][6]*vd*SH_TAS[0]); + Kfusion[20] = SK_TAS*(P[20][4]*SH_TAS[2] - P[20][13]*SH_TAS[2] + P[20][5]*SH_TAS[1] - P[20][14]*SH_TAS[1] + P[20][6]*vd*SH_TAS[0]); + varInnovVtas = 1.0f/SK_TAS; + + // Calculate the measurement innovation + innovVtas = VtasPred - VtasMeas; + // Check the innovation for consistency and don't fuse if > 5Sigma + if ((innovVtas*innovVtas*SK_TAS) < 25.0) + { + // correct the state vector + for (uint8_t j=0; j<=20; j++) + { + states[j] = states[j] - Kfusion[j] * innovVtas; + } + // normalise the quaternion states + float quatMag = sqrt(states[0]*states[0] + states[1]*states[1] + states[2]*states[2] + states[3]*states[3]); + if (quatMag > 1e-12f) + { + for (uint8_t j= 0; j<=3; j++) + { + float quatMagInv = 1.0f/quatMag; + states[j] = states[j] * quatMagInv; + } + } + // correct the covariance P = (I - K*H)*P + // take advantage of the empty columns in H to reduce the + // number of operations + for (uint8_t i = 0; i<=20; i++) + { + for (uint8_t j = 0; j<=3; j++) KH[i][j] = 0.0; + for (uint8_t j = 4; j<=6; j++) + { + KH[i][j] = Kfusion[i] * H_TAS[j]; + } + for (uint8_t j = 7; j<=12; j++) KH[i][j] = 0.0; + for (uint8_t j = 13; j<=14; j++) + { + KH[i][j] = Kfusion[i] * H_TAS[j]; + } + for (uint8_t j = 15; j<=20; j++) KH[i][j] = 0.0; + } + for (uint8_t i = 0; i<=20; i++) + { + for (uint8_t j = 0; j<=20; j++) + { + KHP[i][j] = 0.0; + for (uint8_t k = 4; k<=6; k++) + { + KHP[i][j] = KHP[i][j] + KH[i][k] * P[k][j]; + } + for (uint8_t k = 13; k<=14; k++) + { + KHP[i][j] = KHP[i][j] + KH[i][k] * P[k][j]; + } + } + } + for (uint8_t i = 0; i<=20; i++) + { + for (uint8_t j = 0; j<=20; j++) + { + P[i][j] = P[i][j] - KHP[i][j]; + } + } + } + } + + ForceSymmetry(); + ConstrainVariances(); +} + +void AttPosEKF::zeroRows(float (&covMat)[n_states][n_states], uint8_t first, uint8_t last) +{ + uint8_t row; + uint8_t col; + for (row=first; row<=last; row++) + { + for (col=0; col<n_states; col++) + { + covMat[row][col] = 0.0; + } + } +} + +void AttPosEKF::zeroCols(float (&covMat)[n_states][n_states], uint8_t first, uint8_t last) +{ + uint8_t row; + uint8_t col; + for (col=first; col<=last; col++) + { + for (row=0; row < n_states; row++) + { + covMat[row][col] = 0.0; + } + } +} + +float AttPosEKF::sq(float valIn) +{ + return valIn*valIn; +} + +// Store states in a history array along with time stamp +void AttPosEKF::StoreStates(uint64_t timestamp_ms) +{ + for (unsigned i=0; i<n_states; i++) + storedStates[i][storeIndex] = states[i]; + statetimeStamp[storeIndex] = timestamp_ms; + storeIndex++; + if (storeIndex == data_buffer_size) + storeIndex = 0; +} + +void AttPosEKF::ResetStoredStates() +{ + // reset all stored states + memset(&storedStates[0][0], 0, sizeof(storedStates)); + memset(&statetimeStamp[0], 0, sizeof(statetimeStamp)); + + // reset store index to first + storeIndex = 0; + + // overwrite all existing states + for (unsigned i = 0; i < n_states; i++) { + storedStates[i][storeIndex] = states[i]; + } + + statetimeStamp[storeIndex] = millis(); + + // increment to next storage index + storeIndex++; +} + +// Output the state vector stored at the time that best matches that specified by msec +int AttPosEKF::RecallStates(float statesForFusion[n_states], uint64_t msec) +{ + int ret = 0; + + // int64_t bestTimeDelta = 200; + // unsigned bestStoreIndex = 0; + // for (unsigned storeIndex = 0; storeIndex < data_buffer_size; storeIndex++) + // { + // // The time delta can also end up as negative number, + // // since we might compare future to past or past to future + // // therefore cast to int64. + // int64_t timeDelta = (int64_t)msec - (int64_t)statetimeStamp[storeIndex]; + // if (timeDelta < 0) { + // timeDelta = -timeDelta; + // } + + // if (timeDelta < bestTimeDelta) + // { + // bestStoreIndex = storeIndex; + // bestTimeDelta = timeDelta; + // } + // } + // if (bestTimeDelta < 200) // only output stored state if < 200 msec retrieval error + // { + // for (uint8_t i=0; i < n_states; i++) { + // if (isfinite(storedStates[i][bestStoreIndex])) { + // statesForFusion[i] = storedStates[i][bestStoreIndex]; + // } else if (isfinite(states[i])) { + // statesForFusion[i] = states[i]; + // } else { + // // There is not much we can do here, except reporting the error we just + // // found. + // ret++; + // } + // } + // else // otherwise output current state + // { + for (uint8_t i=0; i < n_states; i++) { + if (isfinite(states[i])) { + statesForFusion[i] = states[i]; + } else { + ret++; + } + } + // } + + return ret; +} + +void AttPosEKF::quat2Tnb(Mat3f &Tnb, const float (&quat)[4]) +{ + // Calculate the nav to body cosine matrix + float q00 = sq(quat[0]); + float q11 = sq(quat[1]); + float q22 = sq(quat[2]); + float q33 = sq(quat[3]); + float q01 = quat[0]*quat[1]; + float q02 = quat[0]*quat[2]; + float q03 = quat[0]*quat[3]; + float q12 = quat[1]*quat[2]; + float q13 = quat[1]*quat[3]; + float q23 = quat[2]*quat[3]; + + Tnb.x.x = q00 + q11 - q22 - q33; + Tnb.y.y = q00 - q11 + q22 - q33; + Tnb.z.z = q00 - q11 - q22 + q33; + Tnb.y.x = 2*(q12 - q03); + Tnb.z.x = 2*(q13 + q02); + Tnb.x.y = 2*(q12 + q03); + Tnb.z.y = 2*(q23 - q01); + Tnb.x.z = 2*(q13 - q02); + Tnb.y.z = 2*(q23 + q01); +} + +void AttPosEKF::quat2Tbn(Mat3f &Tbn, const float (&quat)[4]) +{ + // Calculate the body to nav cosine matrix + float q00 = sq(quat[0]); + float q11 = sq(quat[1]); + float q22 = sq(quat[2]); + float q33 = sq(quat[3]); + float q01 = quat[0]*quat[1]; + float q02 = quat[0]*quat[2]; + float q03 = quat[0]*quat[3]; + float q12 = quat[1]*quat[2]; + float q13 = quat[1]*quat[3]; + float q23 = quat[2]*quat[3]; + + Tbn.x.x = q00 + q11 - q22 - q33; + Tbn.y.y = q00 - q11 + q22 - q33; + Tbn.z.z = q00 - q11 - q22 + q33; + Tbn.x.y = 2*(q12 - q03); + Tbn.x.z = 2*(q13 + q02); + Tbn.y.x = 2*(q12 + q03); + Tbn.y.z = 2*(q23 - q01); + Tbn.z.x = 2*(q13 - q02); + Tbn.z.y = 2*(q23 + q01); +} + +void AttPosEKF::eul2quat(float (&quat)[4], const float (&eul)[3]) +{ + float u1 = cos(0.5f*eul[0]); + float u2 = cos(0.5f*eul[1]); + float u3 = cos(0.5f*eul[2]); + float u4 = sin(0.5f*eul[0]); + float u5 = sin(0.5f*eul[1]); + float u6 = sin(0.5f*eul[2]); + quat[0] = u1*u2*u3+u4*u5*u6; + quat[1] = u4*u2*u3-u1*u5*u6; + quat[2] = u1*u5*u3+u4*u2*u6; + quat[3] = u1*u2*u6-u4*u5*u3; +} + +void AttPosEKF::quat2eul(float (&y)[3], const float (&u)[4]) +{ + y[0] = atan2f((2.0f*(u[2]*u[3]+u[0]*u[1])) , (u[0]*u[0]-u[1]*u[1]-u[2]*u[2]+u[3]*u[3])); + y[1] = -asinf(2.0f*(u[1]*u[3]-u[0]*u[2])); + y[2] = atan2f((2.0f*(u[1]*u[2]+u[0]*u[3])) , (u[0]*u[0]+u[1]*u[1]-u[2]*u[2]-u[3]*u[3])); +} + +void AttPosEKF::calcvelNED(float (&velNED)[3], float gpsCourse, float gpsGndSpd, float gpsVelD) +{ + velNED[0] = gpsGndSpd*cosf(gpsCourse); + velNED[1] = gpsGndSpd*sinf(gpsCourse); + velNED[2] = gpsVelD; +} + +void AttPosEKF::calcposNED(float (&posNED)[3], float lat, float lon, float hgt, float latRef, float lonRef, float hgtRef) +{ + posNED[0] = earthRadius * (lat - latRef); + posNED[1] = earthRadius * cos(latRef) * (lon - lonRef); + posNED[2] = -(hgt - hgtRef); +} + +void AttPosEKF::calcLLH(float (&posNED)[3], float lat, float lon, float hgt, float latRef, float lonRef, float hgtRef) +{ + lat = latRef + posNED[0] * earthRadiusInv; + lon = lonRef + posNED[1] * earthRadiusInv / cos(latRef); + hgt = hgtRef - posNED[2]; +} + +void AttPosEKF::OnGroundCheck() +{ + onGround = (((sq(velNED[0]) + sq(velNED[1]) + sq(velNED[2])) < 4.0f) && (VtasMeas < 8.0f)); + if (staticMode) { + staticMode = !(GPSstatus > GPS_FIX_2D); + } +} + +void AttPosEKF::calcEarthRateNED(Vector3f &omega, float latitude) +{ + //Define Earth rotation vector in the NED navigation frame + omega.x = earthRate*cosf(latitude); + omega.y = 0.0f; + omega.z = -earthRate*sinf(latitude); +} + +void AttPosEKF::CovarianceInit() +{ + // Calculate the initial covariance matrix P + P[0][0] = 0.25f * sq(1.0f*deg2rad); + P[1][1] = 0.25f * sq(1.0f*deg2rad); + P[2][2] = 0.25f * sq(1.0f*deg2rad); + P[3][3] = 0.25f * sq(10.0f*deg2rad); + P[4][4] = sq(0.7); + P[5][5] = P[4][4]; + P[6][6] = sq(0.7); + P[7][7] = sq(15.0); + P[8][8] = P[7][7]; + P[9][9] = sq(5.0); + P[10][10] = sq(0.1*deg2rad*dtIMU); + P[11][11] = P[10][10]; + P[12][12] = P[10][10]; + P[13][13] = sq(8.0f); + P[14][4] = P[13][13]; + P[15][15] = sq(0.02f); + P[16][16] = P[15][15]; + P[17][17] = P[15][15]; + P[18][18] = sq(0.02f); + P[19][19] = P[18][18]; + P[20][20] = P[18][18]; +} + +float AttPosEKF::ConstrainFloat(float val, float min, float max) +{ + return (val > max) ? max : ((val < min) ? min : val); +} + +void AttPosEKF::ConstrainVariances() +{ + if (!numericalProtection) { + return; + } + + // State vector: + // 0-3: quaternions (q0, q1, q2, q3) + // 4-6: Velocity - m/sec (North, East, Down) + // 7-9: Position - m (North, East, Down) + // 10-12: Delta Angle bias - rad (X,Y,Z) + // 13-14: Wind Vector - m/sec (North,East) + // 15-17: Earth Magnetic Field Vector - gauss (North, East, Down) + // 18-20: Body Magnetic Field Vector - gauss (X,Y,Z) + + // Constrain quaternion variances + for (unsigned i = 0; i < 4; i++) { + P[i][i] = ConstrainFloat(P[i][i], 0.0f, 1.0f); + } + + // Constrain velocitie variances + for (unsigned i = 4; i < 7; i++) { + P[i][i] = ConstrainFloat(P[i][i], 0.0f, 1.0e3f); + } + + // Constrain position variances + for (unsigned i = 7; i < 10; i++) { + P[i][i] = ConstrainFloat(P[i][i], 0.0f, 1.0e6f); + } + + // Angle bias variances + for (unsigned i = 10; i < 13; i++) { + P[i][i] = ConstrainFloat(P[i][i], 0.0f, sq(0.175f * dtIMU)); + } + + // Wind velocity variances + for (unsigned i = 13; i < 15; i++) { + P[i][i] = ConstrainFloat(P[i][i], 0.0f, 1.0e3f); + } + + // Earth magnetic field variances + for (unsigned i = 15; i < 18; i++) { + P[i][i] = ConstrainFloat(P[i][i], 0.0f, 1.0f); + } + + // Body magnetic field variances + for (unsigned i = 18; i < 21; i++) { + P[i][i] = ConstrainFloat(P[i][i], 0.0f, 1.0f); + } + +} + +void AttPosEKF::ConstrainStates() +{ + if (!numericalProtection) { + return; + } + + // State vector: + // 0-3: quaternions (q0, q1, q2, q3) + // 4-6: Velocity - m/sec (North, East, Down) + // 7-9: Position - m (North, East, Down) + // 10-12: Delta Angle bias - rad (X,Y,Z) + // 13-14: Wind Vector - m/sec (North,East) + // 15-17: Earth Magnetic Field Vector - gauss (North, East, Down) + // 18-20: Body Magnetic Field Vector - gauss (X,Y,Z) + + + // Constrain quaternion + for (unsigned i = 0; i < 4; i++) { + states[i] = ConstrainFloat(states[i], -1.0f, 1.0f); + } + + // Constrain velocities to what GPS can do for us + for (unsigned i = 4; i < 7; i++) { + states[i] = ConstrainFloat(states[i], -5.0e2f, 5.0e2f); + } + + // Constrain position to a reasonable vehicle range (in meters) + for (unsigned i = 7; i < 9; i++) { + states[i] = ConstrainFloat(states[i], -1.0e6f, 1.0e6f); + } + + // Constrain altitude + states[9] = ConstrainFloat(states[9], -4.0e4f, 1.0e4f); + + // Angle bias limit - set to 8 degrees / sec + for (unsigned i = 10; i < 13; i++) { + states[i] = ConstrainFloat(states[i], -0.12f * dtIMU, 0.12f * dtIMU); + } + + // Wind velocity limits - assume 120 m/s max velocity + for (unsigned i = 13; i < 15; i++) { + states[i] = ConstrainFloat(states[i], -120.0f, 120.0f); + } + + // Earth magnetic field limits (in Gauss) + for (unsigned i = 15; i < 18; i++) { + states[i] = ConstrainFloat(states[i], -1.0f, 1.0f); + } + + // Body magnetic field variances (in Gauss). + // the max offset should be in this range. + for (unsigned i = 18; i < 21; i++) { + states[i] = ConstrainFloat(states[i], -0.5f, 0.5f); + } + +} + +void AttPosEKF::ForceSymmetry() +{ + if (!numericalProtection) { + return; + } + + // Force symmetry on the covariance matrix to prevent ill-conditioning + // of the matrix which would cause the filter to blow-up + for (unsigned i = 1; i < n_states; i++) + { + for (uint8_t j = 0; j < i; j++) + { + P[i][j] = 0.5f * (P[i][j] + P[j][i]); + P[j][i] = P[i][j]; + } + } +} + +bool AttPosEKF::FilterHealthy() +{ + if (!statesInitialised) { + return false; + } + + // XXX Check state vector for NaNs and ill-conditioning + + // Check if any of the major inputs timed out + if (current_ekf_state.posTimeout || current_ekf_state.velTimeout || current_ekf_state.hgtTimeout) { + return false; + } + + // Nothing fired, return ok. + return true; +} + +/** + * Reset the filter position states + * + * This resets the position to the last GPS measurement + * or to zero in case of static position. + */ +void AttPosEKF::ResetPosition(void) +{ + if (staticMode) { + states[7] = 0; + states[8] = 0; + } else if (GPSstatus >= GPS_FIX_3D) { + + // reset the states from the GPS measurements + states[7] = posNE[0]; + states[8] = posNE[1]; + } +} + +/** + * Reset the height state. + * + * This resets the height state with the last altitude measurements + */ +void AttPosEKF::ResetHeight(void) +{ + // write to the state vector + states[9] = -hgtMea; +} + +/** + * Reset the velocity state. + */ +void AttPosEKF::ResetVelocity(void) +{ + if (staticMode) { + states[4] = 0.0f; + states[5] = 0.0f; + states[6] = 0.0f; + } else if (GPSstatus >= GPS_FIX_3D) { + + states[4] = velNED[0]; // north velocity from last reading + states[5] = velNED[1]; // east velocity from last reading + states[6] = velNED[2]; // down velocity from last reading + } +} + + +void AttPosEKF::FillErrorReport(struct ekf_status_report *err) +{ + for (int i = 0; i < n_states; i++) + { + err->states[i] = states[i]; + } + + err->velHealth = current_ekf_state.velHealth; + err->posHealth = current_ekf_state.posHealth; + err->hgtHealth = current_ekf_state.hgtHealth; + err->velTimeout = current_ekf_state.velTimeout; + err->posTimeout = current_ekf_state.posTimeout; + err->hgtTimeout = current_ekf_state.hgtTimeout; +} + +bool AttPosEKF::StatesNaN(struct ekf_status_report *err_report) { + bool err = false; + + // check all states and covariance matrices + for (unsigned i = 0; i < n_states; i++) { + for (unsigned j = 0; j < n_states; j++) { + if (!isfinite(KH[i][j])) { + + err_report->covarianceNaN = true; + err = true; + } // intermediate result used for covariance updates + if (!isfinite(KHP[i][j])) { + + err_report->covarianceNaN = true; + err = true; + } // intermediate result used for covariance updates + if (!isfinite(P[i][j])) { + + err_report->covarianceNaN = true; + err = true; + } // covariance matrix + } + + if (!isfinite(Kfusion[i])) { + + err_report->kalmanGainsNaN = true; + err = true; + } // Kalman gains + + if (!isfinite(states[i])) { + + err_report->statesNaN = true; + err = true; + } // state matrix + } + + if (err) { + FillErrorReport(err_report); + } + + return err; + +} + +/** + * Check the filter inputs and bound its operational state + * + * This check will reset the filter states if required + * due to a failure of consistency or timeout checks. + * it should be run after the measurement data has been + * updated, but before any of the fusion steps are + * executed. + */ +int AttPosEKF::CheckAndBound() +{ + + // Store the old filter state + bool currStaticMode = staticMode; + + // Reset the filter if the states went NaN + if (StatesNaN(&last_ekf_error)) { + + InitializeDynamic(velNED, magDeclination); + + return 1; + } + + // Reset the filter if the IMU data is too old + if (dtIMU > 0.2f) { + + ResetVelocity(); + ResetPosition(); + ResetHeight(); + ResetStoredStates(); + + // that's all we can do here, return + return 2; + } + + // Check if we're on ground - this also sets static mode. + OnGroundCheck(); + + // Check if we switched between states + if (currStaticMode != staticMode) { + ResetVelocity(); + ResetPosition(); + ResetHeight(); + ResetStoredStates(); + + return 3; + } + + return 0; +} + +void AttPosEKF::AttitudeInit(float ax, float ay, float az, float mx, float my, float mz, float declination, float *initQuat) +{ + float initialRoll, initialPitch; + float cosRoll, sinRoll, cosPitch, sinPitch; + float magX, magY; + float initialHdg, cosHeading, sinHeading; + + initialRoll = atan2(-ay, -az); + initialPitch = atan2(ax, -az); + + cosRoll = cosf(initialRoll); + sinRoll = sinf(initialRoll); + cosPitch = cosf(initialPitch); + sinPitch = sinf(initialPitch); + + magX = mx * cosPitch + my * sinRoll * sinPitch + mz * cosRoll * sinPitch; + + magY = my * cosRoll - mz * sinRoll; + + initialHdg = atan2f(-magY, magX); + /* true heading is the mag heading minus declination */ + initialHdg += declination; + + cosRoll = cosf(initialRoll * 0.5f); + sinRoll = sinf(initialRoll * 0.5f); + + cosPitch = cosf(initialPitch * 0.5f); + sinPitch = sinf(initialPitch * 0.5f); + + cosHeading = cosf(initialHdg * 0.5f); + sinHeading = sinf(initialHdg * 0.5f); + + initQuat[0] = cosRoll * cosPitch * cosHeading + sinRoll * sinPitch * sinHeading; + initQuat[1] = sinRoll * cosPitch * cosHeading - cosRoll * sinPitch * sinHeading; + initQuat[2] = cosRoll * sinPitch * cosHeading + sinRoll * cosPitch * sinHeading; + initQuat[3] = cosRoll * cosPitch * sinHeading - sinRoll * sinPitch * cosHeading; +} + +void AttPosEKF::InitializeDynamic(float (&initvelNED)[3], float declination) +{ + + // Clear the init flag + statesInitialised = false; + + magDeclination = declination; + + ZeroVariables(); + + // Calculate initial filter quaternion states from raw measurements + float initQuat[4]; + Vector3f initMagXYZ; + initMagXYZ = magData - magBias; + AttitudeInit(accel.x, accel.y, accel.z, initMagXYZ.x, initMagXYZ.y, initMagXYZ.z, magDeclination, initQuat); + + // Calculate initial Tbn matrix and rotate Mag measurements into NED + // to set initial NED magnetic field states + Mat3f DCM; + quat2Tbn(DCM, initQuat); + Vector3f initMagNED; + initMagXYZ = magData - magBias; + initMagNED.x = DCM.x.x*initMagXYZ.x + DCM.x.y*initMagXYZ.y + DCM.x.z*initMagXYZ.z; + initMagNED.y = DCM.y.x*initMagXYZ.x + DCM.y.y*initMagXYZ.y + DCM.y.z*initMagXYZ.z; + initMagNED.z = DCM.z.x*initMagXYZ.x + DCM.z.y*initMagXYZ.y + DCM.z.z*initMagXYZ.z; + + + + // write to state vector + for (uint8_t j=0; j<=3; j++) states[j] = initQuat[j]; // quaternions + for (uint8_t j=0; j<=2; j++) states[j+4] = initvelNED[j]; // velocities + for (uint8_t j=0; j<=7; j++) states[j+7] = 0.0f; // positiions, dAngBias, windVel + states[15] = initMagNED.x; // Magnetic Field North + states[16] = initMagNED.y; // Magnetic Field East + states[17] = initMagNED.z; // Magnetic Field Down + states[18] = magBias.x; // Magnetic Field Bias X + states[19] = magBias.y; // Magnetic Field Bias Y + states[20] = magBias.z; // Magnetic Field Bias Z + + statesInitialised = true; + + // initialise the covariance matrix + CovarianceInit(); + + //Define Earth rotation vector in the NED navigation frame + calcEarthRateNED(earthRateNED, latRef); + + //Initialise summed variables used by covariance prediction + summedDelAng.x = 0.0f; + summedDelAng.y = 0.0f; + summedDelAng.z = 0.0f; + summedDelVel.x = 0.0f; + summedDelVel.y = 0.0f; + summedDelVel.z = 0.0f; +} + +void AttPosEKF::InitialiseFilter(float (&initvelNED)[3], double referenceLat, double referenceLon, float referenceHgt, float declination) +{ + //store initial lat,long and height + latRef = referenceLat; + lonRef = referenceLon; + hgtRef = referenceHgt; + + memset(&last_ekf_error, 0, sizeof(last_ekf_error)); + + InitializeDynamic(initvelNED, declination); +} + +void AttPosEKF::ZeroVariables() +{ + // Do the data structure init + for (unsigned i = 0; i < n_states; i++) { + for (unsigned j = 0; j < n_states; j++) { + KH[i][j] = 0.0f; // intermediate result used for covariance updates + KHP[i][j] = 0.0f; // intermediate result used for covariance updates + P[i][j] = 0.0f; // covariance matrix + } + + Kfusion[i] = 0.0f; // Kalman gains + states[i] = 0.0f; // state matrix + } + + for (unsigned i = 0; i < data_buffer_size; i++) { + + for (unsigned j = 0; j < n_states; j++) { + storedStates[j][i] = 0.0f; + } + + statetimeStamp[i] = 0; + } + + memset(¤t_ekf_state, 0, sizeof(current_ekf_state)); +} + +void AttPosEKF::GetFilterState(struct ekf_status_report *state) +{ + memcpy(state, ¤t_ekf_state, sizeof(state)); +} + +void AttPosEKF::GetLastErrorState(struct ekf_status_report *last_error) +{ + memcpy(last_error, &last_ekf_error, sizeof(last_error)); +} diff --git a/src/modules/ekf_att_pos_estimator/estimator_21states.h b/src/modules/ekf_att_pos_estimator/estimator_21states.h new file mode 100644 index 000000000..a19ff1995 --- /dev/null +++ b/src/modules/ekf_att_pos_estimator/estimator_21states.h @@ -0,0 +1,247 @@ +#pragma once + +#include "estimator_utilities.h" + +class AttPosEKF { + +public: + + AttPosEKF(); + ~AttPosEKF(); + + /* ############################################## + * + * M A I N F I L T E R P A R A M E T E R S + * + * ########################################### */ + + /* + * parameters are defined here and initialised in + * the InitialiseParameters() (which is just 20 lines down) + */ + + float covTimeStepMax; // maximum time allowed between covariance predictions + float covDelAngMax; // maximum delta angle between covariance predictions + float rngFinderPitch; // pitch angle of laser range finder in radians. Zero is aligned with the Z body axis. Positive is RH rotation about Y body axis. + + float yawVarScale; + float windVelSigma; + float dAngBiasSigma; + float dVelBiasSigma; + float magEarthSigma; + float magBodySigma; + float gndHgtSigma; + + float vneSigma; + float vdSigma; + float posNeSigma; + float posDSigma; + float magMeasurementSigma; + float airspeedMeasurementSigma; + + float gyroProcessNoise; + float accelProcessNoise; + + float EAS2TAS; // ratio f true to equivalent airspeed + + void InitialiseParameters() + { + covTimeStepMax = 0.07f; // maximum time allowed between covariance predictions + covDelAngMax = 0.02f; // maximum delta angle between covariance predictions + rngFinderPitch = 0.0f; // pitch angle of laser range finder in radians. Zero is aligned with the Z body axis. Positive is RH rotation about Y body axis. + EAS2TAS = 1.0f; + + yawVarScale = 1.0f; + windVelSigma = 0.1f; + dAngBiasSigma = 5.0e-7f; + dVelBiasSigma = 1e-4f; + magEarthSigma = 3.0e-4f; + magBodySigma = 3.0e-4f; + gndHgtSigma = 0.02f; // assume 2% terrain gradient 1-sigma + + vneSigma = 0.2f; + vdSigma = 0.3f; + posNeSigma = 2.0f; + posDSigma = 2.0f; + + magMeasurementSigma = 0.05; + airspeedMeasurementSigma = 1.4f; + gyroProcessNoise = 1.4544411e-2f; + accelProcessNoise = 0.5f; + } + + // Global variables + float KH[n_states][n_states]; // intermediate result used for covariance updates + float KHP[n_states][n_states]; // intermediate result used for covariance updates + float P[n_states][n_states]; // covariance matrix + float Kfusion[n_states]; // Kalman gains + float states[n_states]; // state matrix + float storedStates[n_states][data_buffer_size]; // state vectors stored for the last 50 time steps + uint32_t statetimeStamp[data_buffer_size]; // time stamp for each state vector stored + + float statesAtVelTime[n_states]; // States at the effective measurement time for posNE and velNED measurements + float statesAtPosTime[n_states]; // States at the effective measurement time for posNE and velNED measurements + float statesAtHgtTime[n_states]; // States at the effective measurement time for the hgtMea measurement + float statesAtMagMeasTime[n_states]; // filter satates at the effective measurement time + float statesAtVtasMeasTime[n_states]; // filter states at the effective measurement time + + Vector3f correctedDelAng; // delta angles about the xyz body axes corrected for errors (rad) + Vector3f correctedDelVel; // delta velocities along the XYZ body axes corrected for errors (m/s) + Vector3f summedDelAng; // summed delta angles about the xyz body axes corrected for errors (rad) + Vector3f summedDelVel; // summed delta velocities along the XYZ body axes corrected for errors (m/s) + float accNavMag; // magnitude of navigation accel (- used to adjust GPS obs variance (m/s^2) + Vector3f earthRateNED; // earths angular rate vector in NED (rad/s) + Vector3f angRate; // angular rate vector in XYZ body axes measured by the IMU (rad/s) + Vector3f accel; // acceleration vector in XYZ body axes measured by the IMU (m/s^2) + Vector3f dVelIMU; + Vector3f dAngIMU; + float dtIMU; // time lapsed since the last IMU measurement or covariance update (sec) + uint8_t fusionModeGPS; // 0 = GPS outputs 3D velocity, 1 = GPS outputs 2D velocity, 2 = GPS outputs no velocity + float innovVelPos[6]; // innovation output + float varInnovVelPos[6]; // innovation variance output + + float velNED[3]; // North, East, Down velocity obs (m/s) + float posNE[2]; // North, East position obs (m) + float hgtMea; // measured height (m) + float posNED[3]; // North, East Down position (m) + + float innovMag[3]; // innovation output + float varInnovMag[3]; // innovation variance output + Vector3f magData; // magnetometer flux radings in X,Y,Z body axes + float innovVtas; // innovation output + float varInnovVtas; // innovation variance output + float VtasMeas; // true airspeed measurement (m/s) + float magDeclination; + float latRef; // WGS-84 latitude of reference point (rad) + float lonRef; // WGS-84 longitude of reference point (rad) + float hgtRef; // WGS-84 height of reference point (m) + Vector3f magBias; // states representing magnetometer bias vector in XYZ body axes + uint8_t covSkipCount; // Number of state prediction frames (IMU daya updates to skip before doing the covariance prediction + + // GPS input data variables + float gpsCourse; + float gpsVelD; + float gpsLat; + float gpsLon; + float gpsHgt; + uint8_t GPSstatus; + + // Baro input + float baroHgt; + + bool statesInitialised; + + bool fuseVelData; // this boolean causes the posNE and velNED obs to be fused + bool fusePosData; // this boolean causes the posNE and velNED obs to be fused + bool fuseHgtData; // this boolean causes the hgtMea obs to be fused + bool fuseMagData; // boolean true when magnetometer data is to be fused + bool fuseVtasData; // boolean true when airspeed data is to be fused + + bool onGround; ///< boolean true when the flight vehicle is on the ground (not flying) + bool staticMode; ///< boolean true if no position feedback is fused + bool useAirspeed; ///< boolean true if airspeed data is being used + bool useCompass; ///< boolean true if magnetometer data is being used + + struct ekf_status_report current_ekf_state; + struct ekf_status_report last_ekf_error; + + bool numericalProtection; + + unsigned storeIndex; + + +void UpdateStrapdownEquationsNED(); + +void CovariancePrediction(float dt); + +void FuseVelposNED(); + +void FuseMagnetometer(); + +void FuseAirspeed(); + +void zeroRows(float (&covMat)[n_states][n_states], uint8_t first, uint8_t last); + +void zeroCols(float (&covMat)[n_states][n_states], uint8_t first, uint8_t last); + +void quatNorm(float (&quatOut)[4], const float quatIn[4]); + +// store staes along with system time stamp in msces +void StoreStates(uint64_t timestamp_ms); + +/** + * Recall the state vector. + * + * Recalls the vector stored at closest time to the one specified by msec + * + * @return zero on success, integer indicating the number of invalid states on failure. + * Does only copy valid states, if the statesForFusion vector was initialized + * correctly by the caller, the result can be safely used, but is a mixture + * time-wise where valid states were updated and invalid remained at the old + * value. + */ +int RecallStates(float statesForFusion[n_states], uint64_t msec); + +void ResetStoredStates(); + +void quat2Tbn(Mat3f &Tbn, const float (&quat)[4]); + +void calcEarthRateNED(Vector3f &omega, float latitude); + +static void eul2quat(float (&quat)[4], const float (&eul)[3]); + +static void quat2eul(float (&eul)[3], const float (&quat)[4]); + +static void calcvelNED(float (&velNED)[3], float gpsCourse, float gpsGndSpd, float gpsVelD); + +static void calcposNED(float (&posNED)[3], float lat, float lon, float hgt, float latRef, float lonRef, float hgtRef); + +static void calcLLH(float (&posNED)[3], float lat, float lon, float hgt, float latRef, float lonRef, float hgtRef); + +static void quat2Tnb(Mat3f &Tnb, const float (&quat)[4]); + +static float sq(float valIn); + +void OnGroundCheck(); + +void CovarianceInit(); + +void InitialiseFilter(float (&initvelNED)[3], double referenceLat, double referenceLon, float referenceHgt, float declination); + +float ConstrainFloat(float val, float min, float max); + +void ConstrainVariances(); + +void ConstrainStates(); + +void ForceSymmetry(); + +int CheckAndBound(); + +void ResetPosition(); + +void ResetVelocity(); + +void ZeroVariables(); + +void GetFilterState(struct ekf_status_report *state); + +void GetLastErrorState(struct ekf_status_report *last_error); + +bool StatesNaN(struct ekf_status_report *err_report); +void FillErrorReport(struct ekf_status_report *err); + +void InitializeDynamic(float (&initvelNED)[3], float declination); + +protected: + +bool FilterHealthy(); + +void ResetHeight(void); + +void AttitudeInit(float ax, float ay, float az, float mx, float my, float mz, float declination, float *initQuat); + +}; + +uint32_t millis(); + diff --git a/src/modules/ekf_att_pos_estimator/estimator.cpp b/src/modules/ekf_att_pos_estimator/estimator_23states.cpp index 1320b4668..e4b0c2b14 100644 --- a/src/modules/ekf_att_pos_estimator/estimator.cpp +++ b/src/modules/ekf_att_pos_estimator/estimator_23states.cpp @@ -1,143 +1,9 @@ -#include "estimator.h" +#include "estimator_23states.h" #include <string.h> -#include <stdarg.h> - -// Define EKF_DEBUG here to enable the debug print calls -// if the macro is not set, these will be completely -// optimized out by the compiler. -//#define EKF_DEBUG - -#ifdef EKF_DEBUG #include <stdio.h> +#include <stdarg.h> -static void -ekf_debug_print(const char *fmt, va_list args) -{ - fprintf(stderr, "%s: ", "[ekf]"); - vfprintf(stderr, fmt, args); - - fprintf(stderr, "\n"); -} - -static void -ekf_debug(const char *fmt, ...) -{ - va_list args; - - va_start(args, fmt); - ekf_debug_print(fmt, args); -} - -#else - -static void ekf_debug(const char *fmt, ...) { while(0){} } -#endif - -float Vector3f::length(void) const -{ - return sqrt(x*x + y*y + z*z); -} - -void Vector3f::zero(void) -{ - x = 0.0f; - y = 0.0f; - z = 0.0f; -} - -Mat3f::Mat3f() { - identity(); -} - -void Mat3f::identity() { - x.x = 1.0f; - x.y = 0.0f; - x.z = 0.0f; - - y.x = 0.0f; - y.y = 1.0f; - y.z = 0.0f; - - z.x = 0.0f; - z.y = 0.0f; - z.z = 1.0f; -} - -Mat3f Mat3f::transpose(void) const -{ - Mat3f ret = *this; - swap_var(ret.x.y, ret.y.x); - swap_var(ret.x.z, ret.z.x); - swap_var(ret.y.z, ret.z.y); - return ret; -} - -// overload + operator to provide a vector addition -Vector3f operator+( Vector3f vecIn1, Vector3f vecIn2) -{ - Vector3f vecOut; - vecOut.x = vecIn1.x + vecIn2.x; - vecOut.y = vecIn1.y + vecIn2.y; - vecOut.z = vecIn1.z + vecIn2.z; - return vecOut; -} - -// overload - operator to provide a vector subtraction -Vector3f operator-( Vector3f vecIn1, Vector3f vecIn2) -{ - Vector3f vecOut; - vecOut.x = vecIn1.x - vecIn2.x; - vecOut.y = vecIn1.y - vecIn2.y; - vecOut.z = vecIn1.z - vecIn2.z; - return vecOut; -} - -// overload * operator to provide a matrix vector product -Vector3f operator*( Mat3f matIn, Vector3f vecIn) -{ - Vector3f vecOut; - vecOut.x = matIn.x.x*vecIn.x + matIn.x.y*vecIn.y + matIn.x.z*vecIn.z; - vecOut.y = matIn.y.x*vecIn.x + matIn.y.y*vecIn.y + matIn.y.z*vecIn.z; - vecOut.z = matIn.x.x*vecIn.x + matIn.z.y*vecIn.y + matIn.z.z*vecIn.z; - return vecOut; -} - -// overload % operator to provide a vector cross product -Vector3f operator%( Vector3f vecIn1, Vector3f vecIn2) -{ - Vector3f vecOut; - vecOut.x = vecIn1.y*vecIn2.z - vecIn1.z*vecIn2.y; - vecOut.y = vecIn1.z*vecIn2.x - vecIn1.x*vecIn2.z; - vecOut.z = vecIn1.x*vecIn2.y - vecIn1.y*vecIn2.x; - return vecOut; -} - -// overload * operator to provide a vector scaler product -Vector3f operator*(Vector3f vecIn1, float sclIn1) -{ - Vector3f vecOut; - vecOut.x = vecIn1.x * sclIn1; - vecOut.y = vecIn1.y * sclIn1; - vecOut.z = vecIn1.z * sclIn1; - return vecOut; -} - -// overload * operator to provide a vector scaler product -Vector3f operator*(float sclIn1, Vector3f vecIn1) -{ - Vector3f vecOut; - vecOut.x = vecIn1.x * sclIn1; - vecOut.y = vecIn1.y * sclIn1; - vecOut.z = vecIn1.z * sclIn1; - return vecOut; -} - -void swap_var(float &d1, float &d2) -{ - float tmp = d1; - d1 = d2; - d2 = tmp; -} +#define EKF_COVARIANCE_DIVERGED 1.0e8f AttPosEKF::AttPosEKF() @@ -145,7 +11,42 @@ AttPosEKF::AttPosEKF() * instead to allow clean in-air re-initialization. */ { + summedDelAng.zero(); + summedDelVel.zero(); + + fusionModeGPS = 0; + fuseVelData = false; + fusePosData = false; + fuseHgtData = false; + fuseMagData = false; + fuseVtasData = false; + onGround = true; + staticMode = true; + useAirspeed = true; + useCompass = true; + useRangeFinder = true; + numericalProtection = true; + refSet = false; + storeIndex = 0; + gpsHgt = 0.0f; + baroHgt = 0.0f; + GPSstatus = 0; + VtasMeas = 0.0f; + magDeclination = 0.0f; + dAngIMU.zero(); + dVelIMU.zero(); + velNED[0] = 0.0f; + velNED[1] = 0.0f; + velNED[2] = 0.0f; + accelGPSNED[0] = 0.0f; + accelGPSNED[1] = 0.0f; + accelGPSNED[2] = 0.0f; + delAngTotal.zero(); + ekfDiverged = false; + lastReset = 0; + memset(&last_ekf_error, 0, sizeof(last_ekf_error)); + memset(¤t_ekf_state, 0, sizeof(current_ekf_state)); ZeroVariables(); InitialiseParameters(); } @@ -181,6 +82,10 @@ void AttPosEKF::UpdateStrapdownEquationsNED() dVelIMU.y = dVelIMU.y; dVelIMU.z = dVelIMU.z - states[13]; + delAngTotal.x += correctedDelAng.x; + delAngTotal.y += correctedDelAng.y; + delAngTotal.z += correctedDelAng.z; + // Save current measurements Vector3f prevDelAng = correctedDelAng; @@ -199,8 +104,12 @@ void AttPosEKF::UpdateStrapdownEquationsNED() } else { - deltaQuat[0] = cosf(0.5f*rotationMag); - float rotScaler = (sinf(0.5f*rotationMag))/rotationMag; + // We are using double here as we are unsure how small + // the angle differences are and if we get into numeric + // issues with float. The runtime impact is not measurable + // for these quantities. + deltaQuat[0] = cos(0.5*(double)rotationMag); + float rotScaler = (sin(0.5*(double)rotationMag))/(double)rotationMag; deltaQuat[1] = correctedDelAng.x*rotScaler; deltaQuat[2] = correctedDelAng.y*rotScaler; deltaQuat[3] = correctedDelAng.z*rotScaler; @@ -312,7 +221,8 @@ void AttPosEKF::CovariancePrediction(float dt) float nextP[n_states][n_states]; // calculate covariance prediction process noise - for (uint8_t i= 0; i<=9; i++) processNoise[i] = 1.0e-9f; + for (uint8_t i= 0; i<4; i++) processNoise[i] = 1.0e-9f; + for (uint8_t i= 4; i<10; i++) processNoise[i] = 1.0e-9f; for (uint8_t i=10; i<=12; i++) processNoise[i] = dt * dAngBiasSigma; // scale gyro bias noise when on ground to allow for faster bias estimation for (uint8_t i=10; i<=12; i++) processNoise[i] = dt * dAngBiasSigma; @@ -977,20 +887,20 @@ void AttPosEKF::CovariancePrediction(float dt) // propagate for (unsigned i = 0; i <= 13; i++) { P[i][i] = nextP[i][i]; + } - // force symmetry for observable states - // force zero for non-observable states - for (unsigned i = 1; i < n_states; i++) + // force symmetry for observable states + // force zero for non-observable states + for (unsigned i = 1; i < n_states; i++) + { + for (uint8_t j = 0; j < i; j++) { - for (uint8_t j = 0; j < i; j++) - { - if ((i > 13) || (j > 13)) { - P[i][j] = 0.0f; - } else { - P[i][j] = 0.5f * (nextP[i][j] + nextP[j][i]); - } - P[j][i] = P[i][j]; + if ((i > 13) || (j > 13)) { + P[i][j] = 0.0f; + } else { + P[i][j] = 0.5f * (nextP[i][j] + nextP[j][i]); } + P[j][i] = P[i][j]; } } @@ -1020,9 +930,9 @@ void AttPosEKF::FuseVelposNED() { // declare variables used by fault isolation logic - uint32_t gpsRetryTime = 30000; // time in msec before GPS fusion will be retried following innovation consistency failure - uint32_t gpsRetryTimeNoTAS = 5000; // retry time if no TAS measurement available - uint32_t hgtRetryTime = 5000; // height measurement retry time + uint32_t gpsRetryTime = 3000; // time in msec before GPS fusion will be retried following innovation consistency failure + uint32_t gpsRetryTimeNoTAS = 500; // retry time if no TAS measurement available + uint32_t hgtRetryTime = 500; // height measurement retry time uint32_t horizRetryTime; // declare variables used to check measurement errors @@ -1178,7 +1088,7 @@ void AttPosEKF::FuseVelposNED() stateIndex = 4 + obsIndex; // Calculate the measurement innovation, using states from a // different time coordinate if fusing height data - if (obsIndex >= 0 && obsIndex <= 2) + if (obsIndex <= 2) { innovVelPos[obsIndex] = statesAtVelTime[stateIndex] - observation[obsIndex]; } @@ -1193,7 +1103,7 @@ void AttPosEKF::FuseVelposNED() // Calculate the Kalman Gain // Calculate innovation variances - also used for data logging varInnovVelPos[obsIndex] = P[stateIndex][stateIndex] + R_OBS[obsIndex]; - SK = 1.0/varInnovVelPos[obsIndex]; + SK = 1.0/(double)varInnovVelPos[obsIndex]; for (uint8_t i= 0; i<=indexLimit; i++) { Kfusion[i] = P[i][stateIndex]*SK; @@ -1277,7 +1187,7 @@ void AttPosEKF::FuseMagnetometer() // data fit is the only assumption we can make // so we might as well take advantage of the computational efficiencies // associated with sequential fusion - if (useCompass && (fuseMagData || obsIndex == 1 || obsIndex == 2)) + if (useCompass && fuseMagData && (obsIndex < 3)) { // Limit range of states modified when on ground if(!onGround) @@ -1293,7 +1203,7 @@ void AttPosEKF::FuseMagnetometer() // three prediction time steps. // Calculate observation jacobians and Kalman gains - if (fuseMagData) + if (obsIndex == 0) { // Copy required states to local variable names q0 = statesAtMagMeasTime[0]; @@ -1388,11 +1298,6 @@ void AttPosEKF::FuseMagnetometer() Kfusion[22] = SK_MX[0]*(P[22][19] + P[22][1]*SH_MAG[0] + P[22][3]*SH_MAG[2] + P[22][0]*SK_MX[3] - P[22][2]*SK_MX[2] - P[22][16]*SK_MX[1] + P[22][17]*SK_MX[5] - P[22][18]*SK_MX[4]); varInnovMag[0] = 1.0f/SK_MX[0]; innovMag[0] = MagPred[0] - magData.x; - - // reset the observation index to 0 (we start by fusing the X - // measurement) - obsIndex = 0; - fuseMagData = false; } else if (obsIndex == 1) // we are now fusing the Y measurement { @@ -1508,7 +1413,7 @@ void AttPosEKF::FuseMagnetometer() } // Check the innovation for consistency and don't fuse if > 5Sigma - if ((innovMag[obsIndex]*innovMag[obsIndex]/varInnovMag[obsIndex]) < 25.0) + if ((innovMag[obsIndex]*innovMag[obsIndex]/varInnovMag[obsIndex]) < 25.0f) { // correct the state vector for (uint8_t j= 0; j < indexLimit; j++) @@ -1517,7 +1422,7 @@ void AttPosEKF::FuseMagnetometer() } // normalise the quaternion states float quatMag = sqrt(states[0]*states[0] + states[1]*states[1] + states[2]*states[2] + states[3]*states[3]); - if (quatMag > 1e-12) + if (quatMag > 1e-12f) { for (uint8_t j= 0; j<=3; j++) { @@ -1612,7 +1517,7 @@ void AttPosEKF::FuseAirspeed() SH_TAS[0] = 1/(sqrt(sq(ve - vwe) + sq(vn - vwn) + sq(vd))); SH_TAS[1] = (SH_TAS[0]*(2.0f*ve - 2*vwe))/2.0f; SH_TAS[2] = (SH_TAS[0]*(2.0f*vn - 2*vwn))/2.0f; - + float H_TAS[n_states]; for (uint8_t i = 0; i < n_states; i++) H_TAS[i] = 0.0f; H_TAS[4] = SH_TAS[2]; @@ -1661,7 +1566,7 @@ void AttPosEKF::FuseAirspeed() // Calculate the measurement innovation innovVtas = VtasPred - VtasMeas; // Check the innovation for consistency and don't fuse if > 5Sigma - if ((innovVtas*innovVtas*SK_TAS) < 25.0) + if ((innovVtas*innovVtas*SK_TAS) < 25.0f) { // correct the state vector for (uint8_t j=0; j <= 22; j++) @@ -1758,7 +1663,7 @@ void AttPosEKF::FuseRangeFinder() // Need to check that our range finder tilt angle is less than 30 degrees and we are using range finder data SH_RNG[4] = sin(rngFinderPitch); - cosRngTilt = - Tbn.z.x * SH_RNG[4] + Tbn.z.z * cos(rngFinderPitch); + cosRngTilt = - Tbn.z.x * SH_RNG[4] + Tbn.z.z * cosf(rngFinderPitch); if (useRangeFinder && cosRngTilt > 0.87f) { // Calculate observation jacobian and Kalman gain ignoring all states other than the terrain offset @@ -1855,21 +1760,21 @@ int AttPosEKF::RecallStates(float* statesForFusion, uint64_t msec) int64_t bestTimeDelta = 200; unsigned bestStoreIndex = 0; - for (unsigned storeIndex = 0; storeIndex < data_buffer_size; storeIndex++) + for (unsigned storeIndexLocal = 0; storeIndexLocal < data_buffer_size; storeIndexLocal++) { // Work around a GCC compiler bug - we know 64bit support on ARM is // sketchy in GCC. uint64_t timeDelta; - if (msec > statetimeStamp[storeIndex]) { - timeDelta = msec - statetimeStamp[storeIndex]; + if (msec > statetimeStamp[storeIndexLocal]) { + timeDelta = msec - statetimeStamp[storeIndexLocal]; } else { - timeDelta = statetimeStamp[storeIndex] - msec; + timeDelta = statetimeStamp[storeIndexLocal] - msec; } - if (timeDelta < bestTimeDelta) + if (timeDelta < (uint64_t)bestTimeDelta) { - bestStoreIndex = storeIndex; + bestStoreIndex = storeIndexLocal; bestTimeDelta = timeDelta; } } @@ -1926,7 +1831,7 @@ void AttPosEKF::quat2Tnb(Mat3f &Tnb, const float (&quat)[4]) Tnb.y.z = 2*(q23 + q01); } -void AttPosEKF::quat2Tbn(Mat3f &Tbn, const float (&quat)[4]) +void AttPosEKF::quat2Tbn(Mat3f &Tbn_ret, const float (&quat)[4]) { // Calculate the body to nav cosine matrix float q00 = sq(quat[0]); @@ -1940,15 +1845,15 @@ void AttPosEKF::quat2Tbn(Mat3f &Tbn, const float (&quat)[4]) float q13 = quat[1]*quat[3]; float q23 = quat[2]*quat[3]; - Tbn.x.x = q00 + q11 - q22 - q33; - Tbn.y.y = q00 - q11 + q22 - q33; - Tbn.z.z = q00 - q11 - q22 + q33; - Tbn.x.y = 2*(q12 - q03); - Tbn.x.z = 2*(q13 + q02); - Tbn.y.x = 2*(q12 + q03); - Tbn.y.z = 2*(q23 - q01); - Tbn.z.x = 2*(q13 - q02); - Tbn.z.y = 2*(q23 + q01); + Tbn_ret.x.x = q00 + q11 - q22 - q33; + Tbn_ret.y.y = q00 - q11 + q22 - q33; + Tbn_ret.z.z = q00 - q11 - q22 + q33; + Tbn_ret.x.y = 2*(q12 - q03); + Tbn_ret.x.z = 2*(q13 + q02); + Tbn_ret.y.x = 2*(q12 + q03); + Tbn_ret.y.z = 2*(q23 - q01); + Tbn_ret.z.x = 2*(q13 - q02); + Tbn_ret.z.y = 2*(q23 + q01); } void AttPosEKF::eul2quat(float (&quat)[4], const float (&eul)[3]) @@ -1979,17 +1884,17 @@ void AttPosEKF::calcvelNED(float (&velNED)[3], float gpsCourse, float gpsGndSpd, velNED[2] = gpsVelD; } -void AttPosEKF::calcposNED(float (&posNED)[3], double lat, double lon, float hgt, double latRef, double lonRef, float hgtRef) +void AttPosEKF::calcposNED(float (&posNED)[3], double lat, double lon, float hgt, double latReference, double lonReference, float hgtReference) { - posNED[0] = earthRadius * (lat - latRef); - posNED[1] = earthRadius * cos(latRef) * (lon - lonRef); - posNED[2] = -(hgt - hgtRef); + posNED[0] = earthRadius * (lat - latReference); + posNED[1] = earthRadius * cos(latReference) * (lon - lonReference); + posNED[2] = -(hgt - hgtReference); } -void AttPosEKF::calcLLH(float (&posNED)[3], float lat, float lon, float hgt, float latRef, float lonRef, float hgtRef) +void AttPosEKF::calcLLH(float (&posNED)[3], double &lat, double &lon, float &hgt, double latRef, double lonRef, float hgtRef) { - lat = latRef + posNED[0] * earthRadiusInv; - lon = lonRef + posNED[1] * earthRadiusInv / cos(latRef); + lat = latRef + (double)posNED[0] * earthRadiusInv; + lon = lonRef + (double)posNED[1] * earthRadiusInv / cos(latRef); hgt = hgtRef - posNED[2]; } @@ -2194,10 +2099,71 @@ void AttPosEKF::ForceSymmetry() { P[i][j] = 0.5f * (P[i][j] + P[j][i]); P[j][i] = P[i][j]; + + if ((fabsf(P[i][j]) > EKF_COVARIANCE_DIVERGED) || + (fabsf(P[j][i]) > EKF_COVARIANCE_DIVERGED)) { + current_ekf_state.covariancesExcessive = true; + current_ekf_state.error |= true; + InitializeDynamic(velNED, magDeclination); + return; + } + + float symmetric = 0.5f * (P[i][j] + P[j][i]); + P[i][j] = symmetric; + P[j][i] = symmetric; } } } +bool AttPosEKF::GyroOffsetsDiverged() +{ + // Detect divergence by looking for rapid changes of the gyro offset + Vector3f current_bias; + current_bias.x = states[10]; + current_bias.y = states[11]; + current_bias.z = states[12]; + + Vector3f delta = current_bias - lastGyroOffset; + float delta_len = delta.length(); + float delta_len_scaled = 0.0f; + + // Protect against division by zero + if (delta_len > 0.0f) { + float cov_mag = ConstrainFloat((P[10][10] + P[11][11] + P[12][12]), 1e-12f, 1e-8f); + delta_len_scaled = (5e-7 / (double)cov_mag) * (double)delta_len / (double)dtIMU; + } + + bool diverged = (delta_len_scaled > 1.0f); + lastGyroOffset = current_bias; + current_ekf_state.error |= diverged; + current_ekf_state.gyroOffsetsExcessive = diverged; + + return diverged; +} + +bool AttPosEKF::VelNEDDiverged() +{ + Vector3f current_vel; + current_vel.x = states[4]; + current_vel.y = states[5]; + current_vel.z = states[6]; + + Vector3f gps_vel; + gps_vel.x = velNED[0]; + gps_vel.y = velNED[1]; + gps_vel.z = velNED[2]; + + Vector3f delta = current_vel - gps_vel; + float delta_len = delta.length(); + + bool excessive = (delta_len > 20.0f); + + current_ekf_state.error |= excessive; + current_ekf_state.velOffsetExcessive = excessive; + + return excessive; +} + bool AttPosEKF::FilterHealthy() { if (!statesInitialised) { @@ -2262,42 +2228,26 @@ void AttPosEKF::ResetVelocity(void) } } - -void AttPosEKF::FillErrorReport(struct ekf_status_report *err) -{ - for (unsigned i = 0; i < n_states; i++) - { - err->states[i] = states[i]; - } - - err->velHealth = current_ekf_state.velHealth; - err->posHealth = current_ekf_state.posHealth; - err->hgtHealth = current_ekf_state.hgtHealth; - err->velTimeout = current_ekf_state.velTimeout; - err->posTimeout = current_ekf_state.posTimeout; - err->hgtTimeout = current_ekf_state.hgtTimeout; -} - -bool AttPosEKF::StatesNaN(struct ekf_status_report *err_report) { +bool AttPosEKF::StatesNaN() { bool err = false; // check all integrators if (!isfinite(summedDelAng.x) || !isfinite(summedDelAng.y) || !isfinite(summedDelAng.z)) { - err_report->statesNaN = true; + current_ekf_state.angNaN = true; ekf_debug("summedDelAng NaN: x: %f y: %f z: %f", (double)summedDelAng.x, (double)summedDelAng.y, (double)summedDelAng.z); err = true; goto out; } // delta angles if (!isfinite(correctedDelAng.x) || !isfinite(correctedDelAng.y) || !isfinite(correctedDelAng.z)) { - err_report->statesNaN = true; + current_ekf_state.angNaN = true; ekf_debug("correctedDelAng NaN: x: %f y: %f z: %f", (double)correctedDelAng.x, (double)correctedDelAng.y, (double)correctedDelAng.z); err = true; goto out; } // delta angles if (!isfinite(summedDelVel.x) || !isfinite(summedDelVel.y) || !isfinite(summedDelVel.z)) { - err_report->statesNaN = true; + current_ekf_state.summedDelVelNaN = true; ekf_debug("summedDelVel NaN: x: %f y: %f z: %f", (double)summedDelVel.x, (double)summedDelVel.y, (double)summedDelVel.z); err = true; goto out; @@ -2308,7 +2258,7 @@ bool AttPosEKF::StatesNaN(struct ekf_status_report *err_report) { for (unsigned j = 0; j < n_states; j++) { if (!isfinite(KH[i][j])) { - err_report->covarianceNaN = true; + current_ekf_state.KHNaN = true; err = true; ekf_debug("KH NaN"); goto out; @@ -2316,7 +2266,7 @@ bool AttPosEKF::StatesNaN(struct ekf_status_report *err_report) { if (!isfinite(KHP[i][j])) { - err_report->covarianceNaN = true; + current_ekf_state.KHPNaN = true; err = true; ekf_debug("KHP NaN"); goto out; @@ -2324,7 +2274,7 @@ bool AttPosEKF::StatesNaN(struct ekf_status_report *err_report) { if (!isfinite(P[i][j])) { - err_report->covarianceNaN = true; + current_ekf_state.covarianceNaN = true; err = true; ekf_debug("P NaN"); } // covariance matrix @@ -2332,7 +2282,7 @@ bool AttPosEKF::StatesNaN(struct ekf_status_report *err_report) { if (!isfinite(Kfusion[i])) { - err_report->kalmanGainsNaN = true; + current_ekf_state.kalmanGainsNaN = true; ekf_debug("Kfusion NaN"); err = true; goto out; @@ -2340,7 +2290,7 @@ bool AttPosEKF::StatesNaN(struct ekf_status_report *err_report) { if (!isfinite(states[i])) { - err_report->statesNaN = true; + current_ekf_state.statesNaN = true; ekf_debug("states NaN: i: %u val: %f", i, (double)states[i]); err = true; goto out; @@ -2349,7 +2299,7 @@ bool AttPosEKF::StatesNaN(struct ekf_status_report *err_report) { out: if (err) { - FillErrorReport(err_report); + current_ekf_state.error |= true; } return err; @@ -2365,47 +2315,105 @@ out: * updated, but before any of the fusion steps are * executed. */ -int AttPosEKF::CheckAndBound() +int AttPosEKF::CheckAndBound(struct ekf_status_report *last_error) { // Store the old filter state bool currStaticMode = staticMode; + // Limit reset rate to 5 Hz to allow the filter + // to settle + if (millis() - lastReset < 200) { + return 0; + } + + if (ekfDiverged) { + ekfDiverged = false; + } + + int ret = 0; + + // Check if we're on ground - this also sets static mode. + OnGroundCheck(); + // Reset the filter if the states went NaN - if (StatesNaN(&last_ekf_error)) { + if (StatesNaN()) { ekf_debug("re-initializing dynamic"); - InitializeDynamic(velNED, magDeclination); + // Reset and fill error report + InitializeDynamic(velNED, magDeclination); - return 1; + ret = 1; } // Reset the filter if the IMU data is too old if (dtIMU > 0.3f) { + current_ekf_state.imuTimeout = true; + + // Fill error report + GetFilterState(&last_ekf_error); + ResetVelocity(); ResetPosition(); ResetHeight(); ResetStoredStates(); + // Timeout cleared with this reset + current_ekf_state.imuTimeout = false; + // that's all we can do here, return - return 2; + ret = 2; } - // Check if we're on ground - this also sets static mode. - OnGroundCheck(); - // Check if we switched between states if (currStaticMode != staticMode) { + // Fill error report, but not setting error flag + GetFilterState(&last_ekf_error); + ResetVelocity(); ResetPosition(); ResetHeight(); ResetStoredStates(); - return 3; + ret = 3; + } + + // Reset the filter if gyro offsets are excessive + if (GyroOffsetsDiverged()) { + + // Reset and fill error report + InitializeDynamic(velNED, magDeclination); + + // that's all we can do here, return + ret = 4; + } + + // Reset the filter if it diverges too far from GPS + if (VelNEDDiverged()) { + + // Reset and fill error report + InitializeDynamic(velNED, magDeclination); + + // that's all we can do here, return + ret = 5; + } + + // The excessive covariance detection already + // reset the filter. Just need to report here. + if (last_ekf_error.covariancesExcessive) { + ret = 6; + } + + if (ret) { + ekfDiverged = true; + lastReset = millis(); + + // This reads the last error and clears it + GetLastErrorState(last_error); } - return 0; + return ret; } void AttPosEKF::AttitudeInit(float ax, float ay, float az, float mx, float my, float mz, float declination, float *initQuat) @@ -2456,6 +2464,30 @@ void AttPosEKF::AttitudeInit(float ax, float ay, float az, float mx, float my, f void AttPosEKF::InitializeDynamic(float (&initvelNED)[3], float declination) { + if (current_ekf_state.error) { + GetFilterState(&last_ekf_error); + } + + ZeroVariables(); + + // Reset error states + current_ekf_state.error = false; + current_ekf_state.angNaN = false; + current_ekf_state.summedDelVelNaN = false; + current_ekf_state.KHNaN = false; + current_ekf_state.KHPNaN = false; + current_ekf_state.PNaN = false; + current_ekf_state.covarianceNaN = false; + current_ekf_state.kalmanGainsNaN = false; + current_ekf_state.statesNaN = false; + + current_ekf_state.velHealth = true; + //current_ekf_state.posHealth = ?; + //current_ekf_state.hgtHealth = ?; + + current_ekf_state.velTimeout = false; + //current_ekf_state.posTimeout = ?; + //current_ekf_state.hgtTimeout = ?; // Fill variables with valid data velNED[0] = initvelNED[0]; @@ -2494,7 +2526,11 @@ void AttPosEKF::InitializeDynamic(float (&initvelNED)[3], float declination) // write to state vector for (uint8_t j=0; j<=3; j++) states[j] = initQuat[j]; // quaternions for (uint8_t j=4; j<=6; j++) states[j] = initvelNED[j-4]; // velocities - for (uint8_t j=7; j<=15; j++) states[j] = 0.0f; // positions, dAngBias, dVelBias, windVel + // positions: + states[7] = posNE[0]; + states[8] = posNE[1]; + states[9] = -hgtMea; + for (uint8_t j=10; j<=15; j++) states[j] = 0.0f; // dAngBias, dVelBias, windVel states[16] = initMagNED.x; // Magnetic Field North states[17] = initMagNED.y; // Magnetic Field East states[18] = initMagNED.z; // Magnetic Field Down @@ -2525,14 +2561,16 @@ void AttPosEKF::InitialiseFilter(float (&initvelNED)[3], double referenceLat, do hgtRef = referenceHgt; refSet = true; - // we are at reference altitude, so measurement must be zero - hgtMea = 0.0f; + // we are at reference position, so measurement must be zero + posNE[0] = 0.0f; + posNE[1] = 0.0f; + + // we are at an unknown, possibly non-zero altitude - so altitude + // is not reset (hgtMea) // the baro offset must be this difference now baroHgtOffset = baroHgt - referenceHgt; - memset(&last_ekf_error, 0, sizeof(last_ekf_error)); - InitializeDynamic(initvelNED, declination); } @@ -2540,27 +2578,8 @@ void AttPosEKF::ZeroVariables() { // Initialize on-init initialized variables - fusionModeGPS = 0; - covSkipCount = 0; - statesInitialised = false; - fuseVelData = false; - fusePosData = false; - fuseHgtData = false; - fuseMagData = false; - fuseVtasData = false; - onGround = true; - staticMode = true; - useAirspeed = true; - useCompass = true; - useRangeFinder = true; - numericalProtection = true; - refSet = false; + storeIndex = 0; - gpsHgt = 0.0f; - baroHgt = 0.0f; - GPSstatus = 0; - VtasMeas = 0.0f; - magDeclination = 0.0f; // Do the data structure init for (unsigned i = 0; i < n_states; i++) { @@ -2577,9 +2596,7 @@ void AttPosEKF::ZeroVariables() correctedDelAng.zero(); summedDelAng.zero(); summedDelVel.zero(); - - dAngIMU.zero(); - dVelIMU.zero(); + lastGyroOffset.zero(); for (unsigned i = 0; i < data_buffer_size; i++) { @@ -2598,12 +2615,27 @@ void AttPosEKF::ZeroVariables() } -void AttPosEKF::GetFilterState(struct ekf_status_report *state) +void AttPosEKF::GetFilterState(struct ekf_status_report *err) { - memcpy(state, ¤t_ekf_state, sizeof(*state)); + + // Copy states + for (unsigned i = 0; i < n_states; i++) { + current_ekf_state.states[i] = states[i]; + } + current_ekf_state.n_states = n_states; + + memcpy(err, ¤t_ekf_state, sizeof(*err)); + + // err->velHealth = current_ekf_state.velHealth; + // err->posHealth = current_ekf_state.posHealth; + // err->hgtHealth = current_ekf_state.hgtHealth; + // err->velTimeout = current_ekf_state.velTimeout; + // err->posTimeout = current_ekf_state.posTimeout; + // err->hgtTimeout = current_ekf_state.hgtTimeout; } void AttPosEKF::GetLastErrorState(struct ekf_status_report *last_error) { memcpy(last_error, &last_ekf_error, sizeof(*last_error)); + memset(&last_ekf_error, 0, sizeof(last_ekf_error)); } diff --git a/src/modules/ekf_att_pos_estimator/estimator.h b/src/modules/ekf_att_pos_estimator/estimator_23states.h index e821089f2..dc461cfa1 100644 --- a/src/modules/ekf_att_pos_estimator/estimator.h +++ b/src/modules/ekf_att_pos_estimator/estimator_23states.h @@ -1,76 +1,10 @@ -#include <math.h> -#include <stdint.h> - #pragma once -#define GRAVITY_MSS 9.80665f -#define deg2rad 0.017453292f -#define rad2deg 57.295780f -#define pi 3.141592657f -#define earthRate 0.000072921f -#define earthRadius 6378145.0f -#define earthRadiusInv 1.5678540e-7f - -class Vector3f -{ -private: -public: - float x; - float y; - float z; - - float length(void) const; - void zero(void); -}; - -class Mat3f -{ -private: -public: - Vector3f x; - Vector3f y; - Vector3f z; - - Mat3f(); - - void identity(); - Mat3f transpose(void) const; -}; - -Vector3f operator*(float sclIn1, Vector3f vecIn1); -Vector3f operator+( Vector3f vecIn1, Vector3f vecIn2); -Vector3f operator-( Vector3f vecIn1, Vector3f vecIn2); -Vector3f operator*( Mat3f matIn, Vector3f vecIn); -Vector3f operator%( Vector3f vecIn1, Vector3f vecIn2); -Vector3f operator*(Vector3f vecIn1, float sclIn1); - -void swap_var(float &d1, float &d2); +#include "estimator_utilities.h" const unsigned int n_states = 23; const unsigned int data_buffer_size = 50; -enum GPS_FIX { - GPS_FIX_NOFIX = 0, - GPS_FIX_2D = 2, - GPS_FIX_3D = 3 -}; - -struct ekf_status_report { - bool velHealth; - bool posHealth; - bool hgtHealth; - bool velTimeout; - bool posTimeout; - bool hgtTimeout; - uint32_t velFailTime; - uint32_t posFailTime; - uint32_t hgtFailTime; - float states[n_states]; - bool statesNaN; - bool covarianceNaN; - bool kalmanGainsNaN; -}; - class AttPosEKF { public: @@ -141,7 +75,7 @@ public: accelProcessNoise = 0.5f; } - struct { + struct mag_state_struct { unsigned obsIndex; float MagPred[3]; float SH_MAG[9]; @@ -157,7 +91,12 @@ public: float magZbias; float R_MAG; Mat3f DCM; - } magstate; + }; + + struct mag_state_struct magstate; + struct mag_state_struct resetMagState; + + // Global variables @@ -166,6 +105,7 @@ public: float P[n_states][n_states]; // covariance matrix float Kfusion[n_states]; // Kalman gains float states[n_states]; // state matrix + float resetStates[n_states]; float storedStates[n_states][data_buffer_size]; // state vectors stored for the last 50 time steps uint32_t statetimeStamp[data_buffer_size]; // time stamp for each state vector stored @@ -183,6 +123,8 @@ public: float accNavMag; // magnitude of navigation accel (- used to adjust GPS obs variance (m/s^2) Vector3f earthRateNED; // earths angular rate vector in NED (rad/s) Vector3f angRate; // angular rate vector in XYZ body axes measured by the IMU (rad/s) + Vector3f lastGyroOffset; // Last gyro offset + Vector3f delAngTotal; Mat3f Tbn; // transformation matrix from body to NED coordinates Mat3f Tnb; // transformation amtrix from NED to body coordinates @@ -196,11 +138,11 @@ public: float varInnovVelPos[6]; // innovation variance output float velNED[3]; // North, East, Down velocity obs (m/s) + float accelGPSNED[3]; // Acceleration predicted by GPS in earth frame float posNE[2]; // North, East position obs (m) float hgtMea; // measured height (m) float baroHgtOffset; ///< the baro (weather) offset from normalized altitude float rngMea; // Ground distance - float posNED[3]; // North, East Down position (m) float innovMag[3]; // innovation output float varInnovMag[3]; // innovation variance output @@ -243,6 +185,9 @@ public: bool useCompass; ///< boolean true if magnetometer data is being used bool useRangeFinder; ///< true when rangefinder is being used + bool ekfDiverged; + uint64_t lastReset; + struct ekf_status_report current_ekf_state; struct ekf_status_report last_ekf_error; @@ -299,9 +244,9 @@ static void quat2eul(float (&eul)[3], const float (&quat)[4]); static void calcvelNED(float (&velNED)[3], float gpsCourse, float gpsGndSpd, float gpsVelD); -static void calcposNED(float (&posNED)[3], double lat, double lon, float hgt, double latRef, double lonRef, float hgtRef); +void calcposNED(float (&posNED)[3], double lat, double lon, float hgt, double latRef, double lonRef, float hgtRef); -static void calcLLH(float (&posNED)[3], float lat, float lon, float hgt, float latRef, float lonRef, float hgtRef); +static void calcLLH(float (&posNED)[3], double &lat, double &lon, float &hgt, double latRef, double lonRef, float hgtRef); static void quat2Tnb(Mat3f &Tnb, const float (&quat)[4]); @@ -321,7 +266,7 @@ void ConstrainStates(); void ForceSymmetry(); -int CheckAndBound(); +int CheckAndBound(struct ekf_status_report *last_error); void ResetPosition(); @@ -333,8 +278,7 @@ void GetFilterState(struct ekf_status_report *state); void GetLastErrorState(struct ekf_status_report *last_error); -bool StatesNaN(struct ekf_status_report *err_report); -void FillErrorReport(struct ekf_status_report *err); +bool StatesNaN(); void InitializeDynamic(float (&initvelNED)[3], float declination); @@ -342,6 +286,10 @@ protected: bool FilterHealthy(); +bool GyroOffsetsDiverged(); + +bool VelNEDDiverged(); + void ResetHeight(void); void AttitudeInit(float ax, float ay, float az, float mx, float my, float mz, float declination, float *initQuat); diff --git a/src/modules/ekf_att_pos_estimator/estimator_utilities.cpp b/src/modules/ekf_att_pos_estimator/estimator_utilities.cpp new file mode 100644 index 000000000..b4767a0d3 --- /dev/null +++ b/src/modules/ekf_att_pos_estimator/estimator_utilities.cpp @@ -0,0 +1,139 @@ + +#include "estimator_utilities.h" + +// Define EKF_DEBUG here to enable the debug print calls +// if the macro is not set, these will be completely +// optimized out by the compiler. +//#define EKF_DEBUG + +#ifdef EKF_DEBUG +#include <stdio.h> + +static void +ekf_debug_print(const char *fmt, va_list args) +{ + fprintf(stderr, "%s: ", "[ekf]"); + vfprintf(stderr, fmt, args); + + fprintf(stderr, "\n"); +} + +void +ekf_debug(const char *fmt, ...) +{ + va_list args; + + va_start(args, fmt); + ekf_debug_print(fmt, args); +} + +#else + +void ekf_debug(const char *fmt, ...) { while(0){} } +#endif + +float Vector3f::length(void) const +{ + return sqrt(x*x + y*y + z*z); +} + +void Vector3f::zero(void) +{ + x = 0.0f; + y = 0.0f; + z = 0.0f; +} + +Mat3f::Mat3f() { + identity(); +} + +void Mat3f::identity() { + x.x = 1.0f; + x.y = 0.0f; + x.z = 0.0f; + + y.x = 0.0f; + y.y = 1.0f; + y.z = 0.0f; + + z.x = 0.0f; + z.y = 0.0f; + z.z = 1.0f; +} + +Mat3f Mat3f::transpose(void) const +{ + Mat3f ret = *this; + swap_var(ret.x.y, ret.y.x); + swap_var(ret.x.z, ret.z.x); + swap_var(ret.y.z, ret.z.y); + return ret; +} + +// overload + operator to provide a vector addition +Vector3f operator+( Vector3f vecIn1, Vector3f vecIn2) +{ + Vector3f vecOut; + vecOut.x = vecIn1.x + vecIn2.x; + vecOut.y = vecIn1.y + vecIn2.y; + vecOut.z = vecIn1.z + vecIn2.z; + return vecOut; +} + +// overload - operator to provide a vector subtraction +Vector3f operator-( Vector3f vecIn1, Vector3f vecIn2) +{ + Vector3f vecOut; + vecOut.x = vecIn1.x - vecIn2.x; + vecOut.y = vecIn1.y - vecIn2.y; + vecOut.z = vecIn1.z - vecIn2.z; + return vecOut; +} + +// overload * operator to provide a matrix vector product +Vector3f operator*( Mat3f matIn, Vector3f vecIn) +{ + Vector3f vecOut; + vecOut.x = matIn.x.x*vecIn.x + matIn.x.y*vecIn.y + matIn.x.z*vecIn.z; + vecOut.y = matIn.y.x*vecIn.x + matIn.y.y*vecIn.y + matIn.y.z*vecIn.z; + vecOut.z = matIn.x.x*vecIn.x + matIn.z.y*vecIn.y + matIn.z.z*vecIn.z; + return vecOut; +} + +// overload % operator to provide a vector cross product +Vector3f operator%( Vector3f vecIn1, Vector3f vecIn2) +{ + Vector3f vecOut; + vecOut.x = vecIn1.y*vecIn2.z - vecIn1.z*vecIn2.y; + vecOut.y = vecIn1.z*vecIn2.x - vecIn1.x*vecIn2.z; + vecOut.z = vecIn1.x*vecIn2.y - vecIn1.y*vecIn2.x; + return vecOut; +} + +// overload * operator to provide a vector scaler product +Vector3f operator*(Vector3f vecIn1, float sclIn1) +{ + Vector3f vecOut; + vecOut.x = vecIn1.x * sclIn1; + vecOut.y = vecIn1.y * sclIn1; + vecOut.z = vecIn1.z * sclIn1; + return vecOut; +} + +// overload * operator to provide a vector scaler product +Vector3f operator*(float sclIn1, Vector3f vecIn1) +{ + Vector3f vecOut; + vecOut.x = vecIn1.x * sclIn1; + vecOut.y = vecIn1.y * sclIn1; + vecOut.z = vecIn1.z * sclIn1; + return vecOut; +} + +void swap_var(float &d1, float &d2) +{ + float tmp = d1; + d1 = d2; + d2 = tmp; +} diff --git a/src/modules/ekf_att_pos_estimator/estimator_utilities.h b/src/modules/ekf_att_pos_estimator/estimator_utilities.h new file mode 100644 index 000000000..d47568b62 --- /dev/null +++ b/src/modules/ekf_att_pos_estimator/estimator_utilities.h @@ -0,0 +1,82 @@ +#include <math.h> +#include <stdint.h> + +#pragma once + +#define GRAVITY_MSS 9.80665f +#define deg2rad 0.017453292f +#define rad2deg 57.295780f +#define pi 3.141592657f +#define earthRate 0.000072921f +#define earthRadius 6378145.0 +#define earthRadiusInv 1.5678540e-7 + +class Vector3f +{ +private: +public: + float x; + float y; + float z; + + float length(void) const; + void zero(void); +}; + +class Mat3f +{ +private: +public: + Vector3f x; + Vector3f y; + Vector3f z; + + Mat3f(); + + void identity(); + Mat3f transpose(void) const; +}; + +Vector3f operator*(float sclIn1, Vector3f vecIn1); +Vector3f operator+( Vector3f vecIn1, Vector3f vecIn2); +Vector3f operator-( Vector3f vecIn1, Vector3f vecIn2); +Vector3f operator*( Mat3f matIn, Vector3f vecIn); +Vector3f operator%( Vector3f vecIn1, Vector3f vecIn2); +Vector3f operator*(Vector3f vecIn1, float sclIn1); + +void swap_var(float &d1, float &d2); + +enum GPS_FIX { + GPS_FIX_NOFIX = 0, + GPS_FIX_2D = 2, + GPS_FIX_3D = 3 +}; + +struct ekf_status_report { + bool error; + bool velHealth; + bool posHealth; + bool hgtHealth; + bool velTimeout; + bool posTimeout; + bool hgtTimeout; + bool imuTimeout; + uint32_t velFailTime; + uint32_t posFailTime; + uint32_t hgtFailTime; + float states[32]; + unsigned n_states; + bool angNaN; + bool summedDelVelNaN; + bool KHNaN; + bool KHPNaN; + bool PNaN; + bool covarianceNaN; + bool kalmanGainsNaN; + bool statesNaN; + bool gyroOffsetsExcessive; + bool covariancesExcessive; + bool velOffsetExcessive; +}; + +void ekf_debug(const char *fmt, ...);
\ No newline at end of file diff --git a/src/modules/ekf_att_pos_estimator/module.mk b/src/modules/ekf_att_pos_estimator/module.mk index 6fefec2c2..dc5220bf0 100644 --- a/src/modules/ekf_att_pos_estimator/module.mk +++ b/src/modules/ekf_att_pos_estimator/module.mk @@ -39,4 +39,5 @@ MODULE_COMMAND = ekf_att_pos_estimator SRCS = ekf_att_pos_estimator_main.cpp \ ekf_att_pos_estimator_params.c \ - estimator.cpp + estimator_23states.cpp \ + estimator_utilities.cpp diff --git a/src/modules/mavlink/mavlink_main.cpp b/src/modules/mavlink/mavlink_main.cpp index 69b1a4284..9a5e31ef4 100644 --- a/src/modules/mavlink/mavlink_main.cpp +++ b/src/modules/mavlink/mavlink_main.cpp @@ -197,13 +197,14 @@ mavlink_send_uart_bytes(mavlink_channel_t channel, const uint8_t *ch, int length if (buf_free < desired) { /* we don't want to send anything just in half, so return */ + instance->count_txerr(); return; } } ssize_t ret = write(uart, ch, desired); if (ret != desired) { - // XXX overflow perf + instance->count_txerr(); } else { last_write_success_times[(unsigned)channel] = last_write_try_times[(unsigned)channel]; } @@ -249,7 +250,8 @@ Mavlink::Mavlink() : _param_use_hil_gps(0), /* performance counters */ - _loop_perf(perf_alloc(PC_ELAPSED, "mavlink")) + _loop_perf(perf_alloc(PC_ELAPSED, "mavlink_el")), + _txerr_perf(perf_alloc(PC_COUNT, "mavlink_txe")) { _wpm = &_wpm_s; mission.count = 0; @@ -302,6 +304,7 @@ Mavlink::Mavlink() : Mavlink::~Mavlink() { perf_free(_loop_perf); + perf_free(_txerr_perf); if (_task_running) { /* task wakes up every 10ms or so at the longest */ @@ -327,6 +330,12 @@ Mavlink::~Mavlink() } void +Mavlink::count_txerr() +{ + perf_count(_txerr_perf); +} + +void Mavlink::set_mode(enum MAVLINK_MODE mode) { _mode = mode; @@ -2193,11 +2202,20 @@ int Mavlink::start_helper(int argc, char *argv[]) /* create the instance in task context */ Mavlink *instance = new Mavlink(); - /* this will actually only return once MAVLink exits */ - int res = instance->task_main(argc, argv); + int res; - /* delete instance on main thread end */ - delete instance; + if (!instance) { + + /* out of memory */ + res = -ENOMEM; + warnx("OUT OF MEM"); + } else { + /* this will actually only return once MAVLink exits */ + res = instance->task_main(argc, argv); + + /* delete instance on main thread end */ + delete instance; + } return res; } diff --git a/src/modules/mavlink/mavlink_main.h b/src/modules/mavlink/mavlink_main.h index d44db0819..6777d56c3 100644 --- a/src/modules/mavlink/mavlink_main.h +++ b/src/modules/mavlink/mavlink_main.h @@ -215,10 +215,14 @@ public: const mavlink_channel_t get_channel(); + void configure_stream_threadsafe(const char *stream_name, const float rate); + bool _task_should_exit; /**< if true, mavlink task should exit */ int get_mavlink_fd() { return _mavlink_fd; } + MavlinkStream * get_streams() { return _streams; } const + /* Functions for waiting to start transmission until message received. */ void set_has_received_messages(bool received_messages) { _received_messages = received_messages; } @@ -232,6 +236,11 @@ public: void lockMessageBufferMutex(void) { pthread_mutex_lock(&_message_buffer_mutex); } void unlockMessageBufferMutex(void) { pthread_mutex_unlock(&_message_buffer_mutex); } + /** + * Count a transmision error + */ + void count_txerr(); + protected: Mavlink *next; @@ -303,6 +312,7 @@ private: pthread_mutex_t _message_buffer_mutex; perf_counter_t _loop_perf; /**< loop performance counter */ + perf_counter_t _txerr_perf; /**< TX error counter */ bool _param_initialized; param_t _param_system_id; @@ -371,7 +381,6 @@ private: int mavlink_open_uart(int baudrate, const char *uart_name, struct termios *uart_config_original, bool *is_usb); int configure_stream(const char *stream_name, const float rate); - void configure_stream_threadsafe(const char *stream_name, const float rate); int message_buffer_init(int size); diff --git a/src/modules/mavlink/mavlink_messages.cpp b/src/modules/mavlink/mavlink_messages.cpp index 884713479..e1ebc16cc 100644 --- a/src/modules/mavlink/mavlink_messages.cpp +++ b/src/modules/mavlink/mavlink_messages.cpp @@ -232,6 +232,11 @@ public: return "HEARTBEAT"; } + uint8_t get_id() + { + return MAVLINK_MSG_ID_HEARTBEAT; + } + static MavlinkStream *new_instance() { return new MavlinkStreamHeartbeat(); @@ -292,6 +297,11 @@ public: return "SYS_STATUS"; } + uint8_t get_id() + { + return MAVLINK_MSG_ID_SYS_STATUS; + } + static MavlinkStream *new_instance() { return new MavlinkStreamSysStatus(); @@ -343,6 +353,11 @@ public: return "HIGHRES_IMU"; } + uint8_t get_id() + { + return MAVLINK_MSG_ID_HIGHRES_IMU; + } + static MavlinkStream *new_instance() { return new MavlinkStreamHighresIMU(); @@ -428,6 +443,11 @@ public: return "ATTITUDE"; } + uint8_t get_id() + { + return MAVLINK_MSG_ID_ATTITUDE; + } + static MavlinkStream *new_instance() { return new MavlinkStreamAttitude(); @@ -474,6 +494,11 @@ public: return "ATTITUDE_QUATERNION"; } + uint8_t get_id() + { + return MAVLINK_MSG_ID_ATTITUDE_QUATERNION; + } + static MavlinkStream *new_instance() { return new MavlinkStreamAttitudeQuaternion(); @@ -526,6 +551,11 @@ public: return "VFR_HUD"; } + uint8_t get_id() + { + return MAVLINK_MSG_ID_VFR_HUD; + } + static MavlinkStream *new_instance() { return new MavlinkStreamVFRHUD(); @@ -609,6 +639,11 @@ public: return "GPS_RAW_INT"; } + uint8_t get_id() + { + return MAVLINK_MSG_ID_GPS_RAW_INT; + } + static MavlinkStream *new_instance() { return new MavlinkStreamGPSRawInt(); @@ -662,6 +697,11 @@ public: return "GLOBAL_POSITION_INT"; } + uint8_t get_id() + { + return MAVLINK_MSG_ID_GLOBAL_POSITION_INT; + } + static MavlinkStream *new_instance() { return new MavlinkStreamGlobalPositionInt(); @@ -723,6 +763,11 @@ public: return "LOCAL_POSITION_NED"; } + uint8_t get_id() + { + return MAVLINK_MSG_ID_LOCAL_POSITION_NED; + } + static MavlinkStream *new_instance() { return new MavlinkStreamLocalPositionNED(); @@ -774,6 +819,11 @@ public: return "VICON_POSITION_ESTIMATE"; } + uint8_t get_id() + { + return MAVLINK_MSG_ID_VICON_POSITION_ESTIMATE; + } + static MavlinkStream *new_instance() { return new MavlinkStreamViconPositionEstimate(); @@ -824,6 +874,11 @@ public: return "GPS_GLOBAL_ORIGIN"; } + uint8_t get_id() + { + return MAVLINK_MSG_ID_GPS_GLOBAL_ORIGIN; + } + static MavlinkStream *new_instance() { return new MavlinkStreamGPSGlobalOrigin(); @@ -864,6 +919,11 @@ public: return MavlinkStreamServoOutputRaw<N>::get_name_static(); } + uint8_t get_id() + { + return MAVLINK_MSG_ID_SERVO_OUTPUT_RAW; + } + static const char *get_name_static() { switch (N) { @@ -941,6 +1001,11 @@ public: return "HIL_CONTROLS"; } + uint8_t get_id() + { + return MAVLINK_MSG_ID_HIL_CONTROLS; + } + static MavlinkStream *new_instance() { return new MavlinkStreamHILControls(); @@ -1078,6 +1143,11 @@ public: return "GLOBAL_POSITION_SETPOINT_INT"; } + uint8_t get_id() + { + return MAVLINK_MSG_ID_GLOBAL_POSITION_SETPOINT_INT; + } + static MavlinkStream *new_instance() { return new MavlinkStreamGlobalPositionSetpointInt(); @@ -1121,6 +1191,11 @@ public: return "LOCAL_POSITION_SETPOINT"; } + uint8_t get_id() + { + return MAVLINK_MSG_ID_LOCAL_POSITION_SETPOINT; + } + static MavlinkStream *new_instance() { return new MavlinkStreamLocalPositionSetpoint(); @@ -1169,6 +1244,11 @@ public: return "ROLL_PITCH_YAW_THRUST_SETPOINT"; } + uint8_t get_id() + { + return MAVLINK_MSG_ID_ROLL_PITCH_YAW_THRUST_SETPOINT; + } + static MavlinkStream *new_instance() { return new MavlinkStreamRollPitchYawThrustSetpoint(); @@ -1217,6 +1297,11 @@ public: return "ROLL_PITCH_YAW_RATES_THRUST_SETPOINT"; } + uint8_t get_id() + { + return MAVLINK_MSG_ID_ROLL_PITCH_YAW_RATES_THRUST_SETPOINT; + } + static MavlinkStream *new_instance() { return new MavlinkStreamRollPitchYawRatesThrustSetpoint(); @@ -1265,6 +1350,11 @@ public: return "RC_CHANNELS_RAW"; } + uint8_t get_id() + { + return MAVLINK_MSG_ID_RC_CHANNELS_RAW; + } + static MavlinkStream *new_instance() { return new MavlinkStreamRCChannelsRaw(); @@ -1349,6 +1439,11 @@ public: return "MANUAL_CONTROL"; } + uint8_t get_id() + { + return MAVLINK_MSG_ID_MANUAL_CONTROL; + } + static MavlinkStream *new_instance() { return new MavlinkStreamManualControl(); @@ -1398,6 +1493,11 @@ public: return "OPTICAL_FLOW"; } + uint8_t get_id() + { + return MAVLINK_MSG_ID_OPTICAL_FLOW; + } + static MavlinkStream *new_instance() { return new MavlinkStreamOpticalFlow(); @@ -1446,6 +1546,11 @@ public: return "ATTITUDE_CONTROLS"; } + uint8_t get_id() + { + return 0; + } + static MavlinkStream *new_instance() { return new MavlinkStreamAttitudeControls(); @@ -1504,6 +1609,11 @@ public: return "NAMED_VALUE_FLOAT"; } + uint8_t get_id() + { + return MAVLINK_MSG_ID_NAMED_VALUE_FLOAT; + } + static MavlinkStream *new_instance() { return new MavlinkStreamNamedValueFloat(); @@ -1552,6 +1662,11 @@ public: return "CAMERA_CAPTURE"; } + uint8_t get_id() + { + return 0; + } + static MavlinkStream *new_instance() { return new MavlinkStreamCameraCapture(); @@ -1597,6 +1712,11 @@ public: return "DISTANCE_SENSOR"; } + uint8_t get_id() + { + return MAVLINK_MSG_ID_DISTANCE_SENSOR; + } + static MavlinkStream *new_instance() { return new MavlinkStreamDistanceSensor(); diff --git a/src/modules/mavlink/mavlink_receiver.cpp b/src/modules/mavlink/mavlink_receiver.cpp index 59dc79b26..bb977d277 100644 --- a/src/modules/mavlink/mavlink_receiver.cpp +++ b/src/modules/mavlink/mavlink_receiver.cpp @@ -159,6 +159,10 @@ MavlinkReceiver::handle_message(mavlink_message_t *msg) handle_message_heartbeat(msg); break; + case MAVLINK_MSG_ID_REQUEST_DATA_STREAM: + handle_message_request_data_stream(msg); + break; + case MAVLINK_MSG_ID_ENCAPSULATED_DATA: MavlinkFTP::getServer()->handle_message(_mavlink, msg); break; @@ -499,6 +503,24 @@ MavlinkReceiver::handle_message_heartbeat(mavlink_message_t *msg) } void +MavlinkReceiver::handle_message_request_data_stream(mavlink_message_t *msg) +{ + mavlink_request_data_stream_t req; + mavlink_msg_request_data_stream_decode(msg, &req); + + if (req.target_system == mavlink_system.sysid && req.target_component == mavlink_system.compid) { + float rate = req.start_stop ? (1000.0f / req.req_message_rate) : 0.0f; + + MavlinkStream *stream; + LL_FOREACH(_mavlink->get_streams(), stream) { + if (req.req_stream_id == stream->get_id()) { + _mavlink->configure_stream_threadsafe(stream->get_name(), rate); + } + } + } +} + +void MavlinkReceiver::handle_message_hil_sensor(mavlink_message_t *msg) { mavlink_hil_sensor_t imu; diff --git a/src/modules/mavlink/mavlink_receiver.h b/src/modules/mavlink/mavlink_receiver.h index 8e258fec2..040a07480 100644 --- a/src/modules/mavlink/mavlink_receiver.h +++ b/src/modules/mavlink/mavlink_receiver.h @@ -115,6 +115,7 @@ private: void handle_message_radio_status(mavlink_message_t *msg); void handle_message_manual_control(mavlink_message_t *msg); void handle_message_heartbeat(mavlink_message_t *msg); + void handle_message_request_data_stream(mavlink_message_t *msg); void handle_message_hil_sensor(mavlink_message_t *msg); void handle_message_hil_gps(mavlink_message_t *msg); void handle_message_hil_state_quaternion(mavlink_message_t *msg); diff --git a/src/modules/mavlink/mavlink_stream.h b/src/modules/mavlink/mavlink_stream.h index a41ace48e..69809a386 100644 --- a/src/modules/mavlink/mavlink_stream.h +++ b/src/modules/mavlink/mavlink_stream.h @@ -67,6 +67,7 @@ public: static const char *get_name_static(); virtual void subscribe(Mavlink *mavlink) = 0; virtual const char *get_name() const = 0; + virtual uint8_t get_id() = 0; protected: mavlink_channel_t _channel; diff --git a/src/modules/sdlog2/sdlog2.c b/src/modules/sdlog2/sdlog2.c index 19872bbd0..69dc67695 100644 --- a/src/modules/sdlog2/sdlog2.c +++ b/src/modules/sdlog2/sdlog2.c @@ -976,7 +976,8 @@ int sdlog2_thread_main(int argc, char *argv[]) struct log_BATT_s log_BATT; struct log_DIST_s log_DIST; struct log_TELE_s log_TELE; - struct log_ESTM_s log_ESTM; + struct log_EST0_s log_EST0; + struct log_EST1_s log_EST1; struct log_PWR_s log_PWR; struct log_VICN_s log_VICN; struct log_GS0A_s log_GS0A; @@ -1489,15 +1490,21 @@ int sdlog2_thread_main(int argc, char *argv[]) /* --- ESTIMATOR STATUS --- */ if (copy_if_updated(ORB_ID(estimator_status), subs.estimator_status_sub, &buf.estimator_status)) { - log_msg.msg_type = LOG_ESTM_MSG; - unsigned maxcopy = (sizeof(buf.estimator_status.states) < sizeof(log_msg.body.log_ESTM.s)) ? sizeof(buf.estimator_status.states) : sizeof(log_msg.body.log_ESTM.s); - memset(&(log_msg.body.log_ESTM.s), 0, sizeof(log_msg.body.log_ESTM.s)); - memcpy(&(log_msg.body.log_ESTM.s), buf.estimator_status.states, maxcopy); - log_msg.body.log_ESTM.n_states = buf.estimator_status.n_states; - log_msg.body.log_ESTM.states_nan = buf.estimator_status.states_nan; - log_msg.body.log_ESTM.covariance_nan = buf.estimator_status.covariance_nan; - log_msg.body.log_ESTM.kalman_gain_nan = buf.estimator_status.kalman_gain_nan; - LOGBUFFER_WRITE_AND_COUNT(ESTM); + log_msg.msg_type = LOG_EST0_MSG; + unsigned maxcopy0 = (sizeof(buf.estimator_status.states) < sizeof(log_msg.body.log_EST0.s)) ? sizeof(buf.estimator_status.states) : sizeof(log_msg.body.log_EST0.s); + memset(&(log_msg.body.log_EST0.s), 0, sizeof(log_msg.body.log_EST0.s)); + memcpy(&(log_msg.body.log_EST0.s), buf.estimator_status.states, maxcopy0); + log_msg.body.log_EST0.n_states = buf.estimator_status.n_states; + log_msg.body.log_EST0.nan_flags = buf.estimator_status.nan_flags; + log_msg.body.log_EST0.health_flags = buf.estimator_status.health_flags; + log_msg.body.log_EST0.timeout_flags = buf.estimator_status.timeout_flags; + LOGBUFFER_WRITE_AND_COUNT(EST0); + + log_msg.msg_type = LOG_EST1_MSG; + unsigned maxcopy1 = ((sizeof(buf.estimator_status.states) - maxcopy0) < sizeof(log_msg.body.log_EST1.s)) ? (sizeof(buf.estimator_status.states) - maxcopy0) : sizeof(log_msg.body.log_EST1.s); + memset(&(log_msg.body.log_EST1.s), 0, sizeof(log_msg.body.log_EST1.s)); + memcpy(&(log_msg.body.log_EST1.s), buf.estimator_status.states + maxcopy0, maxcopy1); + LOGBUFFER_WRITE_AND_COUNT(EST1); } /* --- TECS STATUS --- */ diff --git a/src/modules/sdlog2/sdlog2_messages.h b/src/modules/sdlog2/sdlog2_messages.h index 5645ebcf1..db35fa4df 100644 --- a/src/modules/sdlog2/sdlog2_messages.h +++ b/src/modules/sdlog2/sdlog2_messages.h @@ -288,15 +288,7 @@ struct log_TELE_s { uint8_t txbuf; }; -/* --- ESTM - ESTIMATOR STATUS --- */ -#define LOG_ESTM_MSG 23 -struct log_ESTM_s { - float s[10]; - uint8_t n_states; - uint8_t states_nan; - uint8_t covariance_nan; - uint8_t kalman_gain_nan; -}; +// ID 23 available /* --- PWR - ONBOARD POWER SYSTEM --- */ #define LOG_PWR_MSG 24 @@ -376,6 +368,22 @@ struct log_WIND_s { float cov_y; }; +/* --- EST0 - ESTIMATOR STATUS --- */ +#define LOG_EST0_MSG 32 +struct log_EST0_s { + float s[12]; + uint8_t n_states; + uint8_t nan_flags; + uint8_t health_flags; + uint8_t timeout_flags; +}; + +/* --- EST1 - ESTIMATOR STATUS --- */ +#define LOG_EST1_MSG 33 +struct log_EST1_s { + float s[16]; +}; + /********** SYSTEM MESSAGES, ID > 0x80 **********/ /* --- TIME - TIME STAMP --- */ @@ -424,7 +432,8 @@ static const struct log_format_s log_formats[] = { LOG_FORMAT(BATT, "ffff", "V,VFilt,C,Discharged"), LOG_FORMAT(DIST, "ffB", "Bottom,BottomRate,Flags"), LOG_FORMAT(TELE, "BBBBHHB", "RSSI,RemRSSI,Noise,RemNoise,RXErr,Fixed,TXBuf"), - LOG_FORMAT(ESTM, "ffffffffffBBBB", "s0,s1,s2,s3,s4,s5,s6,s7,s8,s9,nStat,statNaN,covNaN,kGainNaN"), + LOG_FORMAT(EST0, "ffffffffffffBBBB", "s0,s1,s2,s3,s4,s5,s6,s7,s8,s9,s10,s11,nStat,fNaN,fHealth,fTOut"), + LOG_FORMAT(EST1, "ffffffffffffffff", "s12,s13,s14,s15,s16,s17,s18,s19,s20,s21,s22,s23,s24,s25,s26,s27"), LOG_FORMAT(PWR, "fffBBBBB", "Periph5V,Servo5V,RSSI,UsbOk,BrickOk,ServoOk,PeriphOC,HipwrOC"), LOG_FORMAT(VICN, "ffffff", "X,Y,Z,Roll,Pitch,Yaw"), LOG_FORMAT(GS0A, "BBBBBBBBBBBBBBBB", "s0,s1,s2,s3,s4,s5,s6,s7,s8,s9,s10,s11,s12,s13,s14,s15"), diff --git a/src/modules/uORB/topics/estimator_status.h b/src/modules/uORB/topics/estimator_status.h index 5530cdb21..7f26b505b 100644 --- a/src/modules/uORB/topics/estimator_status.h +++ b/src/modules/uORB/topics/estimator_status.h @@ -64,9 +64,9 @@ struct estimator_status_report { uint64_t timestamp; /**< Timestamp in microseconds since boot */ float states[32]; /**< Internal filter states */ float n_states; /**< Number of states effectively used */ - bool states_nan; /**< If set to true, one of the states is NaN */ - bool covariance_nan; /**< If set to true, the covariance matrix went NaN */ - bool kalman_gain_nan; /**< If set to true, the Kalman gain matrix went NaN */ + uint8_t nan_flags; /**< Bitmask to indicate NaN states */ + uint8_t health_flags; /**< Bitmask to indicate sensor health states (vel, pos, hgt) */ + uint8_t timeout_flags; /**< Bitmask to indicate timeout flags (vel, pos, hgt) */ }; |