ardupilot/libraries/AP_Compass/CompassCalibrator.cpp

/*
   This program is free software: you can redistribute it and/or modify
   it under the terms of the GNU General Public License as published by
   the Free Software Foundation, either version 3 of the License, or
   (at your option) any later version.

   This program is distributed in the hope that it will be useful,
   but WITHOUT ANY WARRANTY; without even the implied warranty of
   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
   GNU General Public License for more details.

   You should have received a copy of the GNU General Public License
   along with this program.  If not, see <http://www.gnu.org/licenses/>.
*/

/*
 * The intention of a magnetometer in a compass application is to measure
 * Earth's magnetic field. Measurements other than those of Earth's magnetic
 * field are considered errors. This algorithm computes a set of correction
 * parameters that null out errors from various sources:
 *
 * - Sensor bias error
 * - "Hard iron" error caused by materials fixed to the vehicle body that
 *     produce static magnetic fields.
 * - Sensor scale-factor error
 * - Sensor cross-axis sensitivity
 * - "Soft iron" error caused by materials fixed to the vehicle body that
 *     distort magnetic fields.
 *
 * This is done by taking a set of samples that are assumed to be the product
 * of rotation in earth's magnetic field and fitting an offset ellipsoid to
 * them, determining the correction to be applied to adjust the samples into an
 * origin-centered sphere.
 *
 * The state machine of this library is described entirely by the
 * compass_cal_status_t enum, and all state transitions are managed by the
 * set_status function. Normally, the library is in the NOT_STARTED state. When
 * the start function is called, the state transitions to WAITING_TO_START,
 * until two conditions are met: the delay as elapsed, and the memory for the
 * sample buffer has been successfully allocated.
 * Once these conditions are met, the state transitions to RUNNING_STEP_ONE, and
 * samples are collected via calls to the new_sample function. These samples are
 * accepted or rejected based on distance to the nearest sample. The samples are
 * assumed to cover the surface of a sphere, and the radius of that sphere is
 * initialized to a conservative value. Based on a circle-packing pattern, the
 * minimum distance is set such that some percentage of the surface of that
 * sphere must be covered by samples.
 *
 * Once the sample buffer is full, a sphere fitting algorithm is run, which
 * computes a new sphere radius. The sample buffer is thinned of samples which
 * no longer meet the acceptance criteria, and the state transitions to
 * RUNNING_STEP_TWO. Samples continue to be collected until the buffer is full
 * again, the full ellipsoid fit is run, and the state transitions to either
 * SUCCESS or FAILED.
 *
 * The fitting algorithm used is Levenberg-Marquardt. See also:
 * http://en.wikipedia.org/wiki/Levenberg%E2%80%93Marquardt_algorithm
 */

#include "CompassCalibrator.h"
#include <AP_HAL/AP_HAL.h>
#include <AP_Math/AP_GeodesicGrid.h>

extern const AP_HAL::HAL& hal;

////////////////////////////////////////////////////////////
///////////////////// PUBLIC INTERFACE /////////////////////
////////////////////////////////////////////////////////////

#ifdef AP_ARMING_COMPASS_OFFSETS_MAX
#define COMPASS_CALIBRATOR_OFS_MAX AP_ARMING_COMPASS_OFFSETS_MAX
#elif CONFIG_HAL_BOARD == HAL_BOARD_SITL
#define COMPASS_CALIBRATOR_OFS_MAX 2000
#else
#define COMPASS_CALIBRATOR_OFS_MAX 1000
#endif

CompassCalibrator::CompassCalibrator():
_tolerance(COMPASS_CAL_DEFAULT_TOLERANCE),
_sample_buffer(nullptr)
{
    clear();
}

void CompassCalibrator::clear() {
    set_status(COMPASS_CAL_NOT_STARTED);
}

void CompassCalibrator::start(bool retry, float delay) {
    if(running()) {
        return;
    }
    _attempt = 1;
    _retry = retry;
    _delay_start_sec = delay;
    _start_time_ms = AP_HAL::millis();
    set_status(COMPASS_CAL_WAITING_TO_START);
}

void CompassCalibrator::get_calibration(Vector3f &offsets, Vector3f &diagonals, Vector3f &offdiagonals) {
    if (_status != COMPASS_CAL_SUCCESS) {
        return;
    }

    offsets = _params.offset;
    diagonals = _params.diag;
    offdiagonals = _params.offdiag;
}

float CompassCalibrator::get_completion_percent() const {
    // first sampling step is 1/3rd of the progress bar
    // never return more than 99% unless _status is COMPASS_CAL_SUCCESS
    switch(_status) {
        case COMPASS_CAL_NOT_STARTED:
        case COMPASS_CAL_WAITING_TO_START:
            return 0.0f;
        case COMPASS_CAL_RUNNING_STEP_ONE:
            return 33.3f * _samples_collected/COMPASS_CAL_NUM_SAMPLES;
        case COMPASS_CAL_RUNNING_STEP_TWO:
            return 33.3f + 65.7f*((float)(_samples_collected-_samples_thinned)/(COMPASS_CAL_NUM_SAMPLES-_samples_thinned));
        case COMPASS_CAL_SUCCESS:
            return 100.0f;
        case COMPASS_CAL_FAILED:
        default:
            return 0.0f;
    };
}

void CompassCalibrator::update_completion_mask(const Vector3f& v)
{
    Matrix3f softiron{
        _params.diag.x,    _params.offdiag.x, _params.offdiag.y,
        _params.offdiag.x, _params.diag.y,    _params.offdiag.z,
        _params.offdiag.y, _params.offdiag.z, _params.diag.z
    };
    Vector3f corrected = softiron * (v + _params.offset);
    int section = AP_GeodesicGrid::section(corrected, true);
    if (section < 0) {
        return;
    }
    _completion_mask[section / 8] |= 1 << (section % 8);
}

void CompassCalibrator::update_completion_mask()
{
    memset(_completion_mask, 0, sizeof(_completion_mask));
    for (int i = 0; i < _samples_collected; i++) {
        update_completion_mask(_sample_buffer[i].get());
    }
}

CompassCalibrator::completion_mask_t& CompassCalibrator::get_completion_mask()
{
    return _completion_mask;
}

bool CompassCalibrator::check_for_timeout() {
    uint32_t tnow = AP_HAL::millis();
    if(running() && tnow - _last_sample_ms > 1000) {
        _retry = false;
        set_status(COMPASS_CAL_FAILED);
        return true;
    }
    return false;
}

void CompassCalibrator::new_sample(const Vector3f& sample) {
    _last_sample_ms = AP_HAL::millis();

    if(_status == COMPASS_CAL_WAITING_TO_START) {
        set_status(COMPASS_CAL_RUNNING_STEP_ONE);
    }

    if(running() && _samples_collected < COMPASS_CAL_NUM_SAMPLES && accept_sample(sample)) {
        update_completion_mask(sample);
        _sample_buffer[_samples_collected].set(sample);
        _samples_collected++;
    }
}

void CompassCalibrator::update(bool &failure) {
    failure = false;

    if(!fitting()) {
        return;
    }

    if(_status == COMPASS_CAL_RUNNING_STEP_ONE) {
        if (_fit_step >= 10) {
            if(is_equal(_fitness,_initial_fitness) || isnan(_fitness)) {           //if true, means that fitness is diverging instead of converging
                set_status(COMPASS_CAL_FAILED);
                failure = true;
            }
            set_status(COMPASS_CAL_RUNNING_STEP_TWO);
        } else {
            if (_fit_step == 0) {
                calc_initial_offset();
            }
            run_sphere_fit();
            _fit_step++;
        }
    } else if(_status == COMPASS_CAL_RUNNING_STEP_TWO) {
        if (_fit_step >= 35) {
            if(fit_acceptable()) {
                set_status(COMPASS_CAL_SUCCESS);
            } else {
                set_status(COMPASS_CAL_FAILED);
                failure = true;
            }
        } else if (_fit_step < 15) {
            run_sphere_fit();
            _fit_step++;
        } else {
            run_ellipsoid_fit();
            _fit_step++;
        }
    }
}

/////////////////////////////////////////////////////////////
////////////////////// PRIVATE METHODS //////////////////////
/////////////////////////////////////////////////////////////
bool CompassCalibrator::running() const {
    return _status == COMPASS_CAL_RUNNING_STEP_ONE || _status == COMPASS_CAL_RUNNING_STEP_TWO;
}

bool CompassCalibrator::fitting() const {
    return running() && _samples_collected == COMPASS_CAL_NUM_SAMPLES;
}

void CompassCalibrator::initialize_fit() {
    //initialize _fitness before starting a fit
    if (_samples_collected != 0) {
        _fitness = calc_mean_squared_residuals(_params);
    } else {
        _fitness = 1.0e30f;
    }
    _ellipsoid_lambda = 1.0f;
    _sphere_lambda = 1.0f;
    _initial_fitness = _fitness;
    _fit_step = 0;
}

void CompassCalibrator::reset_state() {
    _samples_collected = 0;
    _samples_thinned = 0;
    _params.radius = 200;
    _params.offset.zero();
    _params.diag = Vector3f(1.0f,1.0f,1.0f);
    _params.offdiag.zero();

    memset(_completion_mask, 0, sizeof(_completion_mask));
    initialize_fit();
}

bool CompassCalibrator::set_status(compass_cal_status_t status) {
    if (status != COMPASS_CAL_NOT_STARTED && _status == status) {
        return true;
    }

    switch(status) {
        case COMPASS_CAL_NOT_STARTED:
            reset_state();
            _status = COMPASS_CAL_NOT_STARTED;

            if(_sample_buffer != nullptr) {
                free(_sample_buffer);
                _sample_buffer = nullptr;
            }
            return true;

        case COMPASS_CAL_WAITING_TO_START:
            reset_state();
            _status = COMPASS_CAL_WAITING_TO_START;

            set_status(COMPASS_CAL_RUNNING_STEP_ONE);
            return true;

        case COMPASS_CAL_RUNNING_STEP_ONE:
            if(_status != COMPASS_CAL_WAITING_TO_START) {
                return false;
            }

            if(_attempt == 1 && (AP_HAL::millis()-_start_time_ms)*1.0e-3f < _delay_start_sec) {
                return false;
            }

            if (_sample_buffer == nullptr) {
                _sample_buffer =
                        (CompassSample*) malloc(sizeof(CompassSample) *
                                                COMPASS_CAL_NUM_SAMPLES);
            }

            if(_sample_buffer != nullptr) {
                initialize_fit();
                _status = COMPASS_CAL_RUNNING_STEP_ONE;
                return true;
            }

            return false;

        case COMPASS_CAL_RUNNING_STEP_TWO:
            if(_status != COMPASS_CAL_RUNNING_STEP_ONE) {
                return false;
            }
            thin_samples();
            initialize_fit();
            _status = COMPASS_CAL_RUNNING_STEP_TWO;
            return true;

        case COMPASS_CAL_SUCCESS:
            if(_status != COMPASS_CAL_RUNNING_STEP_TWO) {
                return false;
            }

            if(_sample_buffer != nullptr) {
                free(_sample_buffer);
                _sample_buffer = nullptr;
            }

            _status = COMPASS_CAL_SUCCESS;
            return true;

        case COMPASS_CAL_FAILED:
            if(_status == COMPASS_CAL_NOT_STARTED) {
                return false;
            }

            if(_retry && set_status(COMPASS_CAL_WAITING_TO_START)) {
                _attempt++;
                return true;
            }

            if(_sample_buffer != nullptr) {
                free(_sample_buffer);
                _sample_buffer = nullptr;
            }

            _status = COMPASS_CAL_FAILED;
            return true;

        default:
            return false;
    };
}

bool CompassCalibrator::fit_acceptable() {
    if( !isnan(_fitness) &&
        _params.radius > 150 && _params.radius < 950 && //Earth's magnetic field strength range: 250-850mG
        fabsf(_params.offset.x) < COMPASS_CALIBRATOR_OFS_MAX &&
        fabsf(_params.offset.y) < COMPASS_CALIBRATOR_OFS_MAX &&
        fabsf(_params.offset.z) < COMPASS_CALIBRATOR_OFS_MAX &&
        _params.diag.x > 0.2f && _params.diag.x < 5.0f &&
        _params.diag.y > 0.2f && _params.diag.y < 5.0f &&
        _params.diag.z > 0.2f && _params.diag.z < 5.0f &&
        fabsf(_params.offdiag.x) <  1.0f &&      //absolute of sine/cosine output cannot be greater than 1
        fabsf(_params.offdiag.y) <  1.0f &&
        fabsf(_params.offdiag.z) <  1.0f ){

            return _fitness <= sq(_tolerance);
        }
    return false;
}

void CompassCalibrator::thin_samples() {
    if(_sample_buffer == nullptr) {
        return;
    }

    _samples_thinned = 0;
    // shuffle the samples http://en.wikipedia.org/wiki/Fisher%E2%80%93Yates_shuffle
    // this is so that adjacent samples don't get sequentially eliminated
    for(uint16_t i=_samples_collected-1; i>=1; i--) {
        uint16_t j = get_random16() % (i+1);
        CompassSample temp = _sample_buffer[i];
        _sample_buffer[i] = _sample_buffer[j];
        _sample_buffer[j] = temp;
    }

    for(uint16_t i=0; i < _samples_collected; i++) {
        if(!accept_sample(_sample_buffer[i])) {
            _sample_buffer[i] = _sample_buffer[_samples_collected-1];
            _samples_collected --;
            _samples_thinned ++;
        }
    }

    update_completion_mask();
}

/*
 * The sample acceptance distance is determined as follows:
 * For any regular polyhedron with triangular faces, the angle theta subtended
 * by two closest points is defined as
 *
 *      theta = arccos(cos(A)/(1-cos(A)))
 *
 * Where:
 *      A = (4pi/F + pi)/3
 * and
 *      F = 2V - 4 is the number of faces for the polyhedron in consideration,
 *      which depends on the number of vertices V
 *
 * The above equation was proved after solving for spherical triangular excess
 * and related equations.
 */
bool CompassCalibrator::accept_sample(const Vector3f& sample)
{
    static const uint16_t faces = (2 * COMPASS_CAL_NUM_SAMPLES - 4);
    static const float a = (4.0f * M_PI / (3.0f * faces)) + M_PI / 3.0f;
    static const float theta = 0.5f * acosf(cosf(a) / (1.0f - cosf(a)));

    if(_sample_buffer == nullptr) {
        return false;
    }

    float min_distance = _params.radius * 2*sinf(theta/2);

    for (uint16_t i = 0; i<_samples_collected; i++){
        float distance = (sample - _sample_buffer[i].get()).length();
        if(distance < min_distance) {
            return false;
        }
    }
    return true;
}

bool CompassCalibrator::accept_sample(const CompassSample& sample) {
    return accept_sample(sample.get());
}

float CompassCalibrator::calc_residual(const Vector3f& sample, const param_t& params) const {
    Matrix3f softiron(
        params.diag.x    , params.offdiag.x , params.offdiag.y,
        params.offdiag.x , params.diag.y    , params.offdiag.z,
        params.offdiag.y , params.offdiag.z , params.diag.z
    );
    return params.radius - (softiron*(sample+params.offset)).length();
}

float CompassCalibrator::calc_mean_squared_residuals() const
{
    return calc_mean_squared_residuals(_params);
}

float CompassCalibrator::calc_mean_squared_residuals(const param_t& params) const
{
    if(_sample_buffer == nullptr || _samples_collected == 0) {
        return 1.0e30f;
    }
    float sum = 0.0f;
    for(uint16_t i=0; i < _samples_collected; i++){
        Vector3f sample = _sample_buffer[i].get();
        float resid = calc_residual(sample, params);
        sum += sq(resid);
    }
    sum /= _samples_collected;
    return sum;
}

void CompassCalibrator::calc_sphere_jacob(const Vector3f& sample, const param_t& params, float* ret) const{
    const Vector3f &offset = params.offset;
    const Vector3f &diag = params.diag;
    const Vector3f &offdiag = params.offdiag;
    Matrix3f softiron(
        diag.x    , offdiag.x , offdiag.y,
        offdiag.x , diag.y    , offdiag.z,
        offdiag.y , offdiag.z , diag.z
    );

    float A =  (diag.x    * (sample.x + offset.x)) + (offdiag.x * (sample.y + offset.y)) + (offdiag.y * (sample.z + offset.z));
    float B =  (offdiag.x * (sample.x + offset.x)) + (diag.y    * (sample.y + offset.y)) + (offdiag.z * (sample.z + offset.z));
    float C =  (offdiag.y * (sample.x + offset.x)) + (offdiag.z * (sample.y + offset.y)) + (diag.z    * (sample.z + offset.z));
    float length = (softiron*(sample+offset)).length();

    // 0: partial derivative (radius wrt fitness fn) fn operated on sample
    ret[0] = 1.0f;
    // 1-3: partial derivative (offsets wrt fitness fn) fn operated on sample
    ret[1] = -1.0f * (((diag.x    * A) + (offdiag.x * B) + (offdiag.y * C))/length);
    ret[2] = -1.0f * (((offdiag.x * A) + (diag.y    * B) + (offdiag.z * C))/length);
    ret[3] = -1.0f * (((offdiag.y * A) + (offdiag.z * B) + (diag.z    * C))/length);
}

void CompassCalibrator::calc_initial_offset()
{
    // Set initial offset to the average value of the samples
    _params.offset.zero();
    for(uint16_t k = 0; k<_samples_collected; k++) {
        _params.offset -= _sample_buffer[k].get();
    }
    _params.offset /= _samples_collected;
}

void CompassCalibrator::run_sphere_fit()
{
    if(_sample_buffer == nullptr) {
        return;
    }

    const float lma_damping = 10.0f;

    float fitness = _fitness;
    float fit1, fit2;
    param_t fit1_params, fit2_params;
    fit1_params = fit2_params = _params;

    float JTJ[COMPASS_CAL_NUM_SPHERE_PARAMS*COMPASS_CAL_NUM_SPHERE_PARAMS] = { };
    float JTJ2[COMPASS_CAL_NUM_SPHERE_PARAMS*COMPASS_CAL_NUM_SPHERE_PARAMS] = { };
    float JTFI[COMPASS_CAL_NUM_SPHERE_PARAMS] = { };

    // Gauss Newton Part common for all kind of extensions including LM
    for(uint16_t k = 0; k<_samples_collected; k++) {
        Vector3f sample = _sample_buffer[k].get();

        float sphere_jacob[COMPASS_CAL_NUM_SPHERE_PARAMS];

        calc_sphere_jacob(sample, fit1_params, sphere_jacob);

        for(uint8_t i = 0;i < COMPASS_CAL_NUM_SPHERE_PARAMS; i++) {
            // compute JTJ
            for(uint8_t j = 0; j < COMPASS_CAL_NUM_SPHERE_PARAMS; j++) {
                JTJ[i*COMPASS_CAL_NUM_SPHERE_PARAMS+j] += sphere_jacob[i] * sphere_jacob[j];
                JTJ2[i*COMPASS_CAL_NUM_SPHERE_PARAMS+j] += sphere_jacob[i] * sphere_jacob[j];   //a backup JTJ for LM
            }
            // compute JTFI
            JTFI[i] += sphere_jacob[i] * calc_residual(sample, fit1_params);
        }
    }


    //------------------------Levenberg-Marquardt-part-starts-here---------------------------------//
    //refer: http://en.wikipedia.org/wiki/Levenberg%E2%80%93Marquardt_algorithm#Choice_of_damping_parameter
    for(uint8_t i = 0; i < COMPASS_CAL_NUM_SPHERE_PARAMS; i++) {
        JTJ[i*COMPASS_CAL_NUM_SPHERE_PARAMS+i] += _sphere_lambda;
        JTJ2[i*COMPASS_CAL_NUM_SPHERE_PARAMS+i] += _sphere_lambda/lma_damping;
    }

    if(!inverse(JTJ, JTJ, 4)) {
        return;
    }

    if(!inverse(JTJ2, JTJ2, 4)) {
        return;
    }

    for(uint8_t row=0; row < COMPASS_CAL_NUM_SPHERE_PARAMS; row++) {
        for(uint8_t col=0; col < COMPASS_CAL_NUM_SPHERE_PARAMS; col++) {
            fit1_params.get_sphere_params()[row] -= JTFI[col] * JTJ[row*COMPASS_CAL_NUM_SPHERE_PARAMS+col];
            fit2_params.get_sphere_params()[row] -= JTFI[col] * JTJ2[row*COMPASS_CAL_NUM_SPHERE_PARAMS+col];
        }
    }

    fit1 = calc_mean_squared_residuals(fit1_params);
    fit2 = calc_mean_squared_residuals(fit2_params);

    if(fit1 > _fitness && fit2 > _fitness){
        _sphere_lambda *= lma_damping;
    } else if(fit2 < _fitness && fit2 < fit1) {
        _sphere_lambda /= lma_damping;
        fit1_params = fit2_params;
        fitness = fit2;
    } else if(fit1 < _fitness){
        fitness = fit1;
    }
    //--------------------Levenberg-Marquardt-part-ends-here--------------------------------//

    if(!isnan(fitness) && fitness < _fitness) {
        _fitness = fitness;
        _params = fit1_params;
        update_completion_mask();
    }
}



void CompassCalibrator::calc_ellipsoid_jacob(const Vector3f& sample, const param_t& params, float* ret) const{
    const Vector3f &offset = params.offset;
    const Vector3f &diag = params.diag;
    const Vector3f &offdiag = params.offdiag;
    Matrix3f softiron(
        diag.x    , offdiag.x , offdiag.y,
        offdiag.x , diag.y    , offdiag.z,
        offdiag.y , offdiag.z , diag.z
    );

    float A =  (diag.x    * (sample.x + offset.x)) + (offdiag.x * (sample.y + offset.y)) + (offdiag.y * (sample.z + offset.z));
    float B =  (offdiag.x * (sample.x + offset.x)) + (diag.y    * (sample.y + offset.y)) + (offdiag.z * (sample.z + offset.z));
    float C =  (offdiag.y * (sample.x + offset.x)) + (offdiag.z * (sample.y + offset.y)) + (diag.z    * (sample.z + offset.z));
    float length = (softiron*(sample+offset)).length();

    // 0-2: partial derivative (offset wrt fitness fn) fn operated on sample
    ret[0] = -1.0f * (((diag.x    * A) + (offdiag.x * B) + (offdiag.y * C))/length);
    ret[1] = -1.0f * (((offdiag.x * A) + (diag.y    * B) + (offdiag.z * C))/length);
    ret[2] = -1.0f * (((offdiag.y * A) + (offdiag.z * B) + (diag.z    * C))/length);
    // 3-5: partial derivative (diag offset wrt fitness fn) fn operated on sample
    ret[3] = -1.0f * ((sample.x + offset.x) * A)/length;
    ret[4] = -1.0f * ((sample.y + offset.y) * B)/length;
    ret[5] = -1.0f * ((sample.z + offset.z) * C)/length;
    // 6-8: partial derivative (off-diag offset wrt fitness fn) fn operated on sample
    ret[6] = -1.0f * (((sample.y + offset.y) * A) + ((sample.x + offset.x) * B))/length;
    ret[7] = -1.0f * (((sample.z + offset.z) * A) + ((sample.x + offset.x) * C))/length;
    ret[8] = -1.0f * (((sample.z + offset.z) * B) + ((sample.y + offset.y) * C))/length;
}

void CompassCalibrator::run_ellipsoid_fit()
{
    if(_sample_buffer == nullptr) {
        return;
    }

    const float lma_damping = 10.0f;


    float fitness = _fitness;
    float fit1, fit2;
    param_t fit1_params, fit2_params;
    fit1_params = fit2_params = _params;


    float JTJ[COMPASS_CAL_NUM_ELLIPSOID_PARAMS*COMPASS_CAL_NUM_ELLIPSOID_PARAMS] = { };
    float JTJ2[COMPASS_CAL_NUM_ELLIPSOID_PARAMS*COMPASS_CAL_NUM_ELLIPSOID_PARAMS] = { };
    float JTFI[COMPASS_CAL_NUM_ELLIPSOID_PARAMS] = { };

    // Gauss Newton Part common for all kind of extensions including LM
    for(uint16_t k = 0; k<_samples_collected; k++) {
        Vector3f sample = _sample_buffer[k].get();

        float ellipsoid_jacob[COMPASS_CAL_NUM_ELLIPSOID_PARAMS];

        calc_ellipsoid_jacob(sample, fit1_params, ellipsoid_jacob);

        for(uint8_t i = 0;i < COMPASS_CAL_NUM_ELLIPSOID_PARAMS; i++) {
            // compute JTJ
            for(uint8_t j = 0; j < COMPASS_CAL_NUM_ELLIPSOID_PARAMS; j++) {
                JTJ [i*COMPASS_CAL_NUM_ELLIPSOID_PARAMS+j] += ellipsoid_jacob[i] * ellipsoid_jacob[j];
                JTJ2[i*COMPASS_CAL_NUM_ELLIPSOID_PARAMS+j] += ellipsoid_jacob[i] * ellipsoid_jacob[j];
            }
            // compute JTFI
            JTFI[i] += ellipsoid_jacob[i] * calc_residual(sample, fit1_params);
        }
    }



    //------------------------Levenberg-Marquardt-part-starts-here---------------------------------//
    //refer: http://en.wikipedia.org/wiki/Levenberg%E2%80%93Marquardt_algorithm#Choice_of_damping_parameter
    for(uint8_t i = 0; i < COMPASS_CAL_NUM_ELLIPSOID_PARAMS; i++) {
        JTJ[i*COMPASS_CAL_NUM_ELLIPSOID_PARAMS+i] += _ellipsoid_lambda;
        JTJ2[i*COMPASS_CAL_NUM_ELLIPSOID_PARAMS+i] += _ellipsoid_lambda/lma_damping;
    }

    if(!inverse(JTJ, JTJ, 9)) {
        return;
    }

    if(!inverse(JTJ2, JTJ2, 9)) {
        return;
    }

    for(uint8_t row=0; row < COMPASS_CAL_NUM_ELLIPSOID_PARAMS; row++) {
        for(uint8_t col=0; col < COMPASS_CAL_NUM_ELLIPSOID_PARAMS; col++) {
            fit1_params.get_ellipsoid_params()[row] -= JTFI[col] * JTJ[row*COMPASS_CAL_NUM_ELLIPSOID_PARAMS+col];
            fit2_params.get_ellipsoid_params()[row] -= JTFI[col] * JTJ2[row*COMPASS_CAL_NUM_ELLIPSOID_PARAMS+col];
        }
    }

    fit1 = calc_mean_squared_residuals(fit1_params);
    fit2 = calc_mean_squared_residuals(fit2_params);

    if(fit1 > _fitness && fit2 > _fitness){
        _ellipsoid_lambda *= lma_damping;
    } else if(fit2 < _fitness && fit2 < fit1) {
        _ellipsoid_lambda /= lma_damping;
        fit1_params = fit2_params;
        fitness = fit2;
    } else if(fit1 < _fitness){
        fitness = fit1;
    }
    //--------------------Levenberg-part-ends-here--------------------------------//

    if(fitness < _fitness) {
        _fitness = fitness;
        _params = fit1_params;
        update_completion_mask();
    }
}


//////////////////////////////////////////////////////////
//////////// CompassSample public interface //////////////
//////////////////////////////////////////////////////////

#define COMPASS_CAL_SAMPLE_SCALE_TO_FIXED(__X) ((int16_t)constrain_float(roundf(__X*8.0f), INT16_MIN, INT16_MAX))
#define COMPASS_CAL_SAMPLE_SCALE_TO_FLOAT(__X) (__X/8.0f)

Vector3f CompassCalibrator::CompassSample::get() const {
    return Vector3f(COMPASS_CAL_SAMPLE_SCALE_TO_FLOAT(x),
                    COMPASS_CAL_SAMPLE_SCALE_TO_FLOAT(y),
                    COMPASS_CAL_SAMPLE_SCALE_TO_FLOAT(z));
}

void CompassCalibrator::CompassSample::set(const Vector3f &in) {
    x = COMPASS_CAL_SAMPLE_SCALE_TO_FIXED(in.x);
    y = COMPASS_CAL_SAMPLE_SCALE_TO_FIXED(in.y);
    z = COMPASS_CAL_SAMPLE_SCALE_TO_FIXED(in.z);
}