Telegram/KFEstimator.mm

//
//  KFEstimator.m
//  kalman-ios
//
//  Created by Gareth Cross on 12/27/2013.
//  Copyright (c) 2013 gareth. All rights reserved.
//

#import "KFEstimator.h"
#include <mach/mach_time.h>

#include "AttitudeESKF.hpp"
#include <deque>

uint64_t getTime_ns()
{
    static mach_timebase_info_data_t s_timebase_info;
    
    //  get the time scale
    if (s_timebase_info.denom == 0) {
        mach_timebase_info(&s_timebase_info);
    }
    
    return ((mach_absolute_time() * (uint64_t)s_timebase_info.numer) / (uint64_t)s_timebase_info.denom);
}

double getTime()
{
    // mach_absolute_time() returns billionth of seconds
    const double kOneBillion = 1000000000.0;
    return getTime_ns() / kOneBillion;
}

float constrain(float v, float vmin, float vmax)
{
	if (v > vmax) return vmax;
	if (v < vmin) return vmin;
	return v;
}

BOOL skipCalibration = NO;

@interface KFEstimator ()
{
    double lastT;
    
    NSDate * lastDisturbance;
    
    int staticPts;
    matrix<3> mean_g, mean_m;
    matrix<3> max_m, min_m;
    float max_x, min_x, max_y, min_y;
}

@end

@implementation KFEstimator

- (id)init
{
    self = [super init];
    if (self != nil)
    {
        self.gyroCalibrated = NO;
        self.compassCalibrated = NO;
        
        max_m = matrix<3>(-10000.0f, -10000.0f, -10000.0f);
        min_m = matrix<3>( 10000.0f,  10000.0f,  10000.0f);
        
        max_x = max_y = -1.0f;
        min_x = min_y =  1.0f;
        
        _eskf = new AttitudeESKF();
        
        if (skipCalibration) {
            _eskf->m_b = matrix<3> (0.037, -0.0029, -0.0002);
            _eskf->m_mc = matrix<3> (201.5953f, -291.3410f, 93.4031f);
            _eskf->m_mi = matrix<3> (0.35f, 0, 0.936f);
            
            _eskf->m_Q(0,0) = _eskf->m_Q(1,1) = _eskf->m_Q(2,2) = 1.0e-4f;
            
            _eskf->m_R(0,0) = _eskf->m_R(1,1) = _eskf->m_R(2,2) = 0.02f;
            _eskf->m_R = _eskf->m_R * 20;
            
            //  compass
            _eskf->m_R(3,3) = 1.0410;  _eskf->m_R(3,4) = 0.0650;  _eskf->m_R(3,5) = 0.0737;
            _eskf->m_R(4,3) = 0.0650;  _eskf->m_R(4,4) = 1.2123;  _eskf->m_R(4,5) = -0.1402;
            _eskf->m_R(5,3) = 0.0737;  _eskf->m_R(5,4) = -0.1402; _eskf->m_R(5,5) = 1.5370;
            
            //_eskf->m_R = _eskf->m_R * 0.01f;
            
            self.gyroCalibrated = YES;
            self.compassCalibrated = YES;
        }
    }
    return self;
}

- (void)dealloc
{
    if (_eskf) {
        delete _eskf;
    }
}

- (void)readAccel:(CMAcceleration)acceleration
            rates:(CMRotationRate)rotationRate
            field:(CMMagneticField)magneticField
{
    double T = getTime();
    float delta = (float)MAX(MIN(T - lastT, 0.1), 0.01);
    lastT = T;
    
    auto ar = matrix<3>(-acceleration.x, -acceleration.y, -acceleration.z);
    auto gr = matrix<3>(-rotationRate.x, -rotationRate.y, -rotationRate.z);
    auto mr = matrix<3>(-magneticField.x, -magneticField.y, -magneticField.z);
    
    //  get rough estimates of angles
    float phi = asin(-constrain(ar(1), -1.0f, 1.0f));	//	pitch
    float theta = atan2(ar(0), ar(2));                  //	roll

    if (!self.gyroCalibrated)
    {
        if (fabsf(phi) > 0.06f || fabsf(theta) > 0.06f || fabsf(gr(0)) > 0.1f || fabsf(gr(1)) > 0.1f || fabsf(gr(2)) > 0.1f) {
            lastDisturbance = [NSDate date];
            NSLog(@"Disturbed!");
        }
        
        if (lastDisturbance.timeIntervalSinceNow < -2.0 || !lastDisturbance)
        {
            //  at 'rest', record point
            
            mean_g = (mean_g * staticPts + gr) / (staticPts + 1);
            mean_m = (mean_m * staticPts + mr) / (staticPts + 1);
        }
        
        //  300 calibration points, the above method has ~ converged to the real mean
        if (staticPts++ == 300)
        {
            matrix <6,6> R; //  these params were determined in advanced using samples + matlab
            matrix <3,3> Q;
            
            //  gyroscope
            Q(0,0) = Q(1,1) = Q(2,2) = 0.0001f;
            
            //  accelerometer
            R(0,0) = R(1,1) = R(2,2) = 0.01f;
            R = R * 10;
            
            //  compass
            R(3,3) = 1.041;   R(3,4) =  0.065;  R(3,5) =  0.074;
            R(4,3) = 0.065;   R(4,4) =  1.212;  R(4,5) = -0.0140;
            R(5,3) = 0.074;   R(5,4) = -0.014;  R(5,5) =  1.537;
            
            _eskf->Q() = Q;
            _eskf->R() = R;    //  scale R up to smooth results
            
            _eskf->setGyroBias(mean_g);
            
            NSLog(@"Gyro calibrated, gyro bias: %f, %f, %f", mean_g(0), mean_g(1), mean_g(2));
            self.gyroCalibrated = YES;
        }
    }
    else if (!self.compassCalibrated)
    {
        for (int i=0; i < 3; i++) {
            max_m(i) = MAX(max_m(i), mr(i));
            min_m(i) = MIN(min_m(i), mr(i));
        }
        
        max_x = MAX(ar(0), max_x);
        min_x = MIN(ar(0), min_x);
        
        max_y = MAX(ar(1), max_y);
        min_y = MIN(ar(1), min_y);
        
        //  this is a lazy man's magnetometer calibration
        //  condition: swept through close to 180 degrees on both axes
        //  we consider this close enough to a sphere
        if ((max_x - min_x > 1.8f) &&
            (max_y - min_y > 1.8f))
        {
            auto offset = (max_m + min_m) * 0.5f;
            
            //  determine inertial magnetic field (x-axis aligned with field)
            mean_m = mean_m - offset;
            mean_m(0) = std::sqrt(mean_m(0)*mean_m(0) + mean_m(1)*mean_m(1));
            mean_m(1) = 0;
            //mean_m(2) = 0;
           // mean_m.normalize_safe();
            
            NSLog(@"Compass calibrated, offset: %f, %f, %f, inertial: %f, %f, %f", offset(0), offset(1), offset(2),
                  mean_m(0), mean_m(1), mean_m(2));
            
            _eskf->setMagnetometerOffset(offset);
            _eskf->setInertialField(mean_m);
            
            self.compassCalibrated = YES;
        }
    }
    else
    {
        //  we may now estimate everything
        _eskf->predict(gr, delta);
        _eskf->update(ar, mr, true);   //  true = use compass, false = integrate freely on yaw axis
    }
}

@end
3.6 2016-02-25 01:03:51 +01:00			`//`
			`// KFEstimator.m`
			`// kalman-ios`
			`//`
			`// Created by Gareth Cross on 12/27/2013.`
			`// Copyright (c) 2013 gareth. All rights reserved.`
			`//`

			`#import "KFEstimator.h"`
			`#include <mach/mach_time.h>`

			`#include "AttitudeESKF.hpp"`
			`#include <deque>`

			`uint64_t getTime_ns()`
			`{`
			`static mach_timebase_info_data_t s_timebase_info;`

			`// get the time scale`
			`if (s_timebase_info.denom == 0) {`
			`mach_timebase_info(&s_timebase_info);`
			`}`

			`return ((mach_absolute_time() * (uint64_t)s_timebase_info.numer) / (uint64_t)s_timebase_info.denom);`
			`}`

			`double getTime()`
			`{`
			`// mach_absolute_time() returns billionth of seconds`
			`const double kOneBillion = 1000000000.0;`
			`return getTime_ns() / kOneBillion;`
			`}`

			`float constrain(float v, float vmin, float vmax)`
			`{`
			`if (v > vmax) return vmax;`
			`if (v < vmin) return vmin;`
			`return v;`
			`}`

			`BOOL skipCalibration = NO;`

			`@interface KFEstimator ()`
			`{`
			`double lastT;`

			`NSDate * lastDisturbance;`

			`int staticPts;`
			`matrix<3> mean_g, mean_m;`
			`matrix<3> max_m, min_m;`
			`float max_x, min_x, max_y, min_y;`
			`}`

			`@end`

			`@implementation KFEstimator`

			`- (id)init`
			`{`
			`self = [super init];`
			`if (self != nil)`
			`{`
			`self.gyroCalibrated = NO;`
			`self.compassCalibrated = NO;`

			`max_m = matrix<3>(-10000.0f, -10000.0f, -10000.0f);`
			`min_m = matrix<3>( 10000.0f, 10000.0f, 10000.0f);`

			`max_x = max_y = -1.0f;`
			`min_x = min_y = 1.0f;`

			`_eskf = new AttitudeESKF();`

			`if (skipCalibration) {`
			`_eskf->m_b = matrix<3> (0.037, -0.0029, -0.0002);`
			`_eskf->m_mc = matrix<3> (201.5953f, -291.3410f, 93.4031f);`
			`_eskf->m_mi = matrix<3> (0.35f, 0, 0.936f);`

			`_eskf->m_Q(0,0) = _eskf->m_Q(1,1) = _eskf->m_Q(2,2) = 1.0e-4f;`

			`_eskf->m_R(0,0) = _eskf->m_R(1,1) = _eskf->m_R(2,2) = 0.02f;`
			`_eskf->m_R = _eskf->m_R * 20;`

			`// compass`
			`_eskf->m_R(3,3) = 1.0410; _eskf->m_R(3,4) = 0.0650; _eskf->m_R(3,5) = 0.0737;`
			`_eskf->m_R(4,3) = 0.0650; _eskf->m_R(4,4) = 1.2123; _eskf->m_R(4,5) = -0.1402;`
			`_eskf->m_R(5,3) = 0.0737; _eskf->m_R(5,4) = -0.1402; _eskf->m_R(5,5) = 1.5370;`

			`//_eskf->m_R = _eskf->m_R * 0.01f;`

			`self.gyroCalibrated = YES;`
			`self.compassCalibrated = YES;`
			`}`
			`}`
			`return self;`
			`}`

			`- (void)dealloc`
			`{`
			`if (_eskf) {`
			`delete _eskf;`
			`}`
			`}`

			`- (void)readAccel:(CMAcceleration)acceleration`
			`rates:(CMRotationRate)rotationRate`
			`field:(CMMagneticField)magneticField`
			`{`
			`double T = getTime();`
			`float delta = (float)MAX(MIN(T - lastT, 0.1), 0.01);`
			`lastT = T;`

			`auto ar = matrix<3>(-acceleration.x, -acceleration.y, -acceleration.z);`
			`auto gr = matrix<3>(-rotationRate.x, -rotationRate.y, -rotationRate.z);`
			`auto mr = matrix<3>(-magneticField.x, -magneticField.y, -magneticField.z);`

			`// get rough estimates of angles`
			`float phi = asin(-constrain(ar(1), -1.0f, 1.0f)); // pitch`
			`float theta = atan2(ar(0), ar(2)); // roll`

			`if (!self.gyroCalibrated)`
			`{`
			`if (fabsf(phi) > 0.06f \|\| fabsf(theta) > 0.06f \|\| fabsf(gr(0)) > 0.1f \|\| fabsf(gr(1)) > 0.1f \|\| fabsf(gr(2)) > 0.1f) {`
			`lastDisturbance = [NSDate date];`
			`NSLog(@"Disturbed!");`
			`}`

			`if (lastDisturbance.timeIntervalSinceNow < -2.0 \|\| !lastDisturbance)`
			`{`
			`// at 'rest', record point`

			`mean_g = (mean_g * staticPts + gr) / (staticPts + 1);`
			`mean_m = (mean_m * staticPts + mr) / (staticPts + 1);`
			`}`

			`// 300 calibration points, the above method has ~ converged to the real mean`
			`if (staticPts++ == 300)`
			`{`
			`matrix <6,6> R; // these params were determined in advanced using samples + matlab`
			`matrix <3,3> Q;`

			`// gyroscope`
			`Q(0,0) = Q(1,1) = Q(2,2) = 0.0001f;`

			`// accelerometer`
			`R(0,0) = R(1,1) = R(2,2) = 0.01f;`
			`R = R * 10;`

			`// compass`
			`R(3,3) = 1.041; R(3,4) = 0.065; R(3,5) = 0.074;`
			`R(4,3) = 0.065; R(4,4) = 1.212; R(4,5) = -0.0140;`
			`R(5,3) = 0.074; R(5,4) = -0.014; R(5,5) = 1.537;`

			`_eskf->Q() = Q;`
			`_eskf->R() = R; // scale R up to smooth results`

			`_eskf->setGyroBias(mean_g);`

			`NSLog(@"Gyro calibrated, gyro bias: %f, %f, %f", mean_g(0), mean_g(1), mean_g(2));`
			`self.gyroCalibrated = YES;`
			`}`
			`}`
			`else if (!self.compassCalibrated)`
			`{`
			`for (int i=0; i < 3; i++) {`
			`max_m(i) = MAX(max_m(i), mr(i));`
			`min_m(i) = MIN(min_m(i), mr(i));`
			`}`

			`max_x = MAX(ar(0), max_x);`
			`min_x = MIN(ar(0), min_x);`

			`max_y = MAX(ar(1), max_y);`
			`min_y = MIN(ar(1), min_y);`

			`// this is a lazy man's magnetometer calibration`
			`// condition: swept through close to 180 degrees on both axes`
			`// we consider this close enough to a sphere`
			`if ((max_x - min_x > 1.8f) &&`
			`(max_y - min_y > 1.8f))`
			`{`
			`auto offset = (max_m + min_m) * 0.5f;`

			`// determine inertial magnetic field (x-axis aligned with field)`
			`mean_m = mean_m - offset;`
			`mean_m(0) = std::sqrt(mean_m(0)mean_m(0) + mean_m(1)mean_m(1));`
			`mean_m(1) = 0;`
			`//mean_m(2) = 0;`
			`// mean_m.normalize_safe();`

			`NSLog(@"Compass calibrated, offset: %f, %f, %f, inertial: %f, %f, %f", offset(0), offset(1), offset(2),`
			`mean_m(0), mean_m(1), mean_m(2));`

			`_eskf->setMagnetometerOffset(offset);`
			`_eskf->setInertialField(mean_m);`

			`self.compassCalibrated = YES;`
			`}`
			`}`
			`else`
			`{`
			`// we may now estimate everything`
			`_eskf->predict(gr, delta);`
			`_eskf->update(ar, mr, true); // true = use compass, false = integrate freely on yaw axis`
			`}`
			`}`

			`@end`