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/*M///////////////////////////////////////////////////////////////////////////////////////
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//
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// IMPORTANT: READ BEFORE DOWNLOADING, COPYING, INSTALLING OR USING.
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//
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// By downloading, copying, installing or using the software you agree to this license.
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// If you do not agree to this license, do not download, install,
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// copy or use the software.
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//
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//
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// Intel License Agreement
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// For Open Source Computer Vision Library
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//
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// Copyright (C) 2000, Intel Corporation, all rights reserved.
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// Third party copyrights are property of their respective owners.
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//
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// Redistribution and use in source and binary forms, with or without modification,
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// are permitted provided that the following conditions are met:
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//
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// * Redistribution's of source code must retain the above copyright notice,
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// this list of conditions and the following disclaimer.
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//
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// * Redistribution's in binary form must reproduce the above copyright notice,
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// this list of conditions and the following disclaimer in the documentation
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// and/or other materials provided with the distribution.
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//
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// * The name of Intel Corporation may not be used to endorse or promote products
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// derived from this software without specific prior written permission.
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//
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// This software is provided by the copyright holders and contributors "as is" and
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// any express or implied warranties, including, but not limited to, the implied
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// warranties of merchantability and fitness for a particular purpose are disclaimed.
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// In no event shall the Intel Corporation or contributors be liable for any direct,
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// indirect, incidental, special, exemplary, or consequential damages
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// (including, but not limited to, procurement of substitute goods or services;
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// loss of use, data, or profits; or business interruption) however caused
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// and on any theory of liability, whether in contract, strict liability,
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// or tort (including negligence or otherwise) arising in any way out of
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// the use of this software, even if advised of the possibility of such damage.
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//
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//M*/
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#include "precomp.hpp"
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CV_IMPL CvKalman*
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cvCreateKalman( int DP, int MP, int CP )
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{
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CvKalman *kalman = 0;
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if( DP <= 0 || MP <= 0 )
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CV_Error( CV_StsOutOfRange,
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"state and measurement vectors must have positive number of dimensions" );
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if( CP < 0 )
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CP = DP;
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/* allocating memory for the structure */
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kalman = (CvKalman *)cvAlloc( sizeof( CvKalman ));
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memset( kalman, 0, sizeof(*kalman));
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kalman->DP = DP;
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kalman->MP = MP;
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kalman->CP = CP;
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kalman->state_pre = cvCreateMat( DP, 1, CV_32FC1 );
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cvZero( kalman->state_pre );
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kalman->state_post = cvCreateMat( DP, 1, CV_32FC1 );
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cvZero( kalman->state_post );
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kalman->transition_matrix = cvCreateMat( DP, DP, CV_32FC1 );
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cvSetIdentity( kalman->transition_matrix );
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kalman->process_noise_cov = cvCreateMat( DP, DP, CV_32FC1 );
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cvSetIdentity( kalman->process_noise_cov );
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kalman->measurement_matrix = cvCreateMat( MP, DP, CV_32FC1 );
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cvZero( kalman->measurement_matrix );
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kalman->measurement_noise_cov = cvCreateMat( MP, MP, CV_32FC1 );
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cvSetIdentity( kalman->measurement_noise_cov );
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kalman->error_cov_pre = cvCreateMat( DP, DP, CV_32FC1 );
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kalman->error_cov_post = cvCreateMat( DP, DP, CV_32FC1 );
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cvZero( kalman->error_cov_post );
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kalman->gain = cvCreateMat( DP, MP, CV_32FC1 );
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if( CP > 0 )
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{
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kalman->control_matrix = cvCreateMat( DP, CP, CV_32FC1 );
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cvZero( kalman->control_matrix );
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}
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kalman->temp1 = cvCreateMat( DP, DP, CV_32FC1 );
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kalman->temp2 = cvCreateMat( MP, DP, CV_32FC1 );
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kalman->temp3 = cvCreateMat( MP, MP, CV_32FC1 );
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kalman->temp4 = cvCreateMat( MP, DP, CV_32FC1 );
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kalman->temp5 = cvCreateMat( MP, 1, CV_32FC1 );
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#if 1
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kalman->PosterState = kalman->state_pre->data.fl;
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kalman->PriorState = kalman->state_post->data.fl;
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kalman->DynamMatr = kalman->transition_matrix->data.fl;
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kalman->MeasurementMatr = kalman->measurement_matrix->data.fl;
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kalman->MNCovariance = kalman->measurement_noise_cov->data.fl;
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kalman->PNCovariance = kalman->process_noise_cov->data.fl;
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kalman->KalmGainMatr = kalman->gain->data.fl;
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kalman->PriorErrorCovariance = kalman->error_cov_pre->data.fl;
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kalman->PosterErrorCovariance = kalman->error_cov_post->data.fl;
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#endif
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return kalman;
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}
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CV_IMPL void
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cvReleaseKalman( CvKalman** _kalman )
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{
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CvKalman *kalman;
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if( !_kalman )
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CV_Error( CV_StsNullPtr, "" );
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kalman = *_kalman;
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if( !kalman )
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return;
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/* freeing the memory */
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cvReleaseMat( &kalman->state_pre );
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cvReleaseMat( &kalman->state_post );
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cvReleaseMat( &kalman->transition_matrix );
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cvReleaseMat( &kalman->control_matrix );
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cvReleaseMat( &kalman->measurement_matrix );
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cvReleaseMat( &kalman->process_noise_cov );
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cvReleaseMat( &kalman->measurement_noise_cov );
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cvReleaseMat( &kalman->error_cov_pre );
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cvReleaseMat( &kalman->gain );
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cvReleaseMat( &kalman->error_cov_post );
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cvReleaseMat( &kalman->temp1 );
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cvReleaseMat( &kalman->temp2 );
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cvReleaseMat( &kalman->temp3 );
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cvReleaseMat( &kalman->temp4 );
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cvReleaseMat( &kalman->temp5 );
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memset( kalman, 0, sizeof(*kalman));
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/* deallocating the structure */
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cvFree( _kalman );
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}
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CV_IMPL const CvMat*
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cvKalmanPredict( CvKalman* kalman, const CvMat* control )
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{
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if( !kalman )
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CV_Error( CV_StsNullPtr, "" );
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/* update the state */
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/* x'(k) = A*x(k) */
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cvMatMulAdd( kalman->transition_matrix, kalman->state_post, 0, kalman->state_pre );
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if( control && kalman->CP > 0 )
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/* x'(k) = x'(k) + B*u(k) */
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cvMatMulAdd( kalman->control_matrix, control, kalman->state_pre, kalman->state_pre );
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/* update error covariance matrices */
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/* temp1 = A*P(k) */
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cvMatMulAdd( kalman->transition_matrix, kalman->error_cov_post, 0, kalman->temp1 );
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/* P'(k) = temp1*At + Q */
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cvGEMM( kalman->temp1, kalman->transition_matrix, 1, kalman->process_noise_cov, 1,
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kalman->error_cov_pre, CV_GEMM_B_T );
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/* handle the case when there will be measurement before the next predict */
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cvCopy(kalman->state_pre, kalman->state_post);
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return kalman->state_pre;
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}
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CV_IMPL const CvMat*
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cvKalmanCorrect( CvKalman* kalman, const CvMat* measurement )
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{
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if( !kalman || !measurement )
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CV_Error( CV_StsNullPtr, "" );
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/* temp2 = H*P'(k) */
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cvMatMulAdd( kalman->measurement_matrix, kalman->error_cov_pre, 0, kalman->temp2 );
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/* temp3 = temp2*Ht + R */
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cvGEMM( kalman->temp2, kalman->measurement_matrix, 1,
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kalman->measurement_noise_cov, 1, kalman->temp3, CV_GEMM_B_T );
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/* temp4 = inv(temp3)*temp2 = Kt(k) */
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cvSolve( kalman->temp3, kalman->temp2, kalman->temp4, CV_SVD );
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/* K(k) */
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cvTranspose( kalman->temp4, kalman->gain );
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/* temp5 = z(k) - H*x'(k) */
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cvGEMM( kalman->measurement_matrix, kalman->state_pre, -1, measurement, 1, kalman->temp5 );
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/* x(k) = x'(k) + K(k)*temp5 */
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cvMatMulAdd( kalman->gain, kalman->temp5, kalman->state_pre, kalman->state_post );
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/* P(k) = P'(k) - K(k)*temp2 */
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cvGEMM( kalman->gain, kalman->temp2, -1, kalman->error_cov_pre, 1,
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kalman->error_cov_post, 0 );
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return kalman->state_post;
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}
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namespace cv
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{
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KalmanFilter::KalmanFilter() {}
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KalmanFilter::KalmanFilter(int dynamParams, int measureParams, int controlParams, int type)
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{
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init(dynamParams, measureParams, controlParams, type);
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}
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void KalmanFilter::init(int DP, int MP, int CP, int type)
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{
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CV_Assert( DP > 0 && MP > 0 );
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CV_Assert( type == CV_32F || type == CV_64F );
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CP = std::max(CP, 0);
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statePre = Mat::zeros(DP, 1, type);
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statePost = Mat::zeros(DP, 1, type);
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transitionMatrix = Mat::eye(DP, DP, type);
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processNoiseCov = Mat::eye(DP, DP, type);
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measurementMatrix = Mat::zeros(MP, DP, type);
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measurementNoiseCov = Mat::eye(MP, MP, type);
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errorCovPre = Mat::zeros(DP, DP, type);
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errorCovPost = Mat::zeros(DP, DP, type);
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gain = Mat::zeros(DP, MP, type);
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if( CP > 0 )
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controlMatrix = Mat::zeros(DP, CP, type);
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else
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controlMatrix.release();
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temp1.create(DP, DP, type);
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temp2.create(MP, DP, type);
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temp3.create(MP, MP, type);
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temp4.create(MP, DP, type);
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temp5.create(MP, 1, type);
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}
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const Mat& KalmanFilter::predict(const Mat& control)
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{
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// update the state: x'(k) = A*x(k)
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statePre = transitionMatrix*statePost;
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if( control.data )
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// x'(k) = x'(k) + B*u(k)
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statePre += controlMatrix*control;
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// update error covariance matrices: temp1 = A*P(k)
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temp1 = transitionMatrix*errorCovPost;
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// P'(k) = temp1*At + Q
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gemm(temp1, transitionMatrix, 1, processNoiseCov, 1, errorCovPre, GEMM_2_T);
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// handle the case when there will be measurement before the next predict.
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statePre.copyTo(statePost);
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errorCovPre.copyTo(errorCovPost);
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return statePre;
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}
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const Mat& KalmanFilter::correct(const Mat& measurement)
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{
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// temp2 = H*P'(k)
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temp2 = measurementMatrix * errorCovPre;
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// temp3 = temp2*Ht + R
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gemm(temp2, measurementMatrix, 1, measurementNoiseCov, 1, temp3, GEMM_2_T);
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// temp4 = inv(temp3)*temp2 = Kt(k)
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solve(temp3, temp2, temp4, DECOMP_SVD);
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// K(k)
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gain = temp4.t();
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// temp5 = z(k) - H*x'(k)
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temp5 = measurement - measurementMatrix*statePre;
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// x(k) = x'(k) + K(k)*temp5
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statePost = statePre + gain*temp5;
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// P(k) = P'(k) - K(k)*temp2
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errorCovPost = errorCovPre - gain*temp2;
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return statePost;
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}
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};
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