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#include "SMCalibrationWorker.h"
 1 
#include "SMCalibrationWorker.h"
2 
#include "SMCalibrationParameters.h"
 2 
#include "SMCalibrationParameters.h"
3 
 
 3 
 
4 
#include "cvtools.h"
 4 
#include "cvtools.h"
5 
 
 5 
 
6 
#include <QSettings>
 6 
#include <QSettings>
7 
 
 7 
 
8 
void SMCalibrationWorker::performCalibration(std::vector<SMCalibrationSet> calibrationData){
 8 
void SMCalibrationWorker::performCalibration(std::vector<SMCalibrationSet> calibrationData){
9 
 
 9 
 
10 
    QSettings settings;
 10 
    QSettings settings;
11 
 
 11 
 
12 
    // Number of saddle points on calibration pattern
 12 
    // Number of saddle points on calibration pattern
13 
    int checkerCountX = settings.value("calibration/checkerCountX", 22).toInt();
 13 
    int checkerCountX = settings.value("calibration/checkerCountX", 22).toInt();
14 
    int checkerCountY = settings.value("calibration/checkerCountY", 13).toInt();
 14 
    int checkerCountY = settings.value("calibration/checkerCountY", 13).toInt();
15 
    cv::Size checkerCount(checkerCountX, checkerCountY);
 15 
    cv::Size checkerCount(checkerCountX, checkerCountY);
16 
 
 16 
 
17 
    int nSets = calibrationData.size();
 17 
    int nSets = calibrationData.size();
18 
 
 18 
 
19 
    std::vector< std::vector<cv::Point2f> > qc0, qc1;
 19 
    std::vector< std::vector<cv::Point2f> > qc0, qc1;
20 
    std::vector<float> angles;
 20 
    std::vector<float> angles;
21 
 
 21 
 
22 
    // Loop through calibration sets
 22 
    // Loop through calibration sets
23 
    for(int i=0; i<nSets; i++){
 23 
    for(int i=0; i<nSets; i++){
24 
 
 24 
 
25 
        SMCalibrationSet SMCalibrationSetI = calibrationData[i];
 25 
        SMCalibrationSet SMCalibrationSetI = calibrationData[i];
26 
 
 26 
 
27 
        if(!SMCalibrationSetI.checked)
 27 
        if(!SMCalibrationSetI.checked)
28 
            continue;
 28 
            continue;
29 
 
 29 
 
30 
        // Camera 0
 30 
        // Camera 0
31 
        std::vector<cv::Point2f> qci0;
 31 
        std::vector<cv::Point2f> qci0;
32 
        // Extract checker corners
 32 
        // Extract checker corners
33 
        bool success0 = cv::findChessboardCorners(SMCalibrationSetI.frame0, checkerCount, qci0, cv::CALIB_CB_ADAPTIVE_THRESH + cv::CALIB_CB_FAST_CHECK);
 33 
        bool success0 = cv::findChessboardCorners(SMCalibrationSetI.frame0, checkerCount, qci0, cv::CALIB_CB_ADAPTIVE_THRESH + cv::CALIB_CB_FAST_CHECK);
34 
        if(success0){
 34 
        if(success0){
- 
 
 35 
            // Convert bayer to grayscale
35 
            cv::Mat gray;
 36 
            cv::Mat gray;
36 
            cv::cvtColor(SMCalibrationSetI.frame0, gray, CV_RGB2GRAY);
 37 
            cv::cvtColor(SMCalibrationSetI.frame0, gray, CV_BayerBG2GRAY);
- 
 
 38 
            cv::cvtColor(gray, gray, CV_RGB2GRAY);
37 
            cv::cornerSubPix(gray, qci0, cv::Size(5, 5), cv::Size(-1, -1),cv::TermCriteria(CV_TERMCRIT_EPS + CV_TERMCRIT_ITER, 20, 0.001));
 39 
            cv::cornerSubPix(gray, qci0, cv::Size(5, 5), cv::Size(-1, -1),cv::TermCriteria(CV_TERMCRIT_EPS + CV_TERMCRIT_ITER, 20, 0.001));
38 
            // Draw colored chessboard
 40 
            // Draw colored chessboard
39 
            SMCalibrationSetI.frame0Result = SMCalibrationSetI.frame0.clone();
 41 
            SMCalibrationSetI.frame0Result = SMCalibrationSetI.frame0.clone();
40 
            cvtools::drawChessboardCorners(SMCalibrationSetI.frame0Result, checkerCount, qci0, success0, 10);
 42 
            cvtools::drawChessboardCorners(SMCalibrationSetI.frame0Result, checkerCount, qci0, success0, 10);
41 
        }
 43 
        }
42 
 
 44 
 
43 
        emit newFrameResult(i, 0, success0, SMCalibrationSetI.frame0Result);
 45 
        emit newFrameResult(i, 0, success0, SMCalibrationSetI.frame0Result);
44 
 
 46 
 
45 
        // Camera 1
 47 
        // Camera 1
46 
        std::vector<cv::Point2f> qci1;
 48 
        std::vector<cv::Point2f> qci1;
47 
        // Extract checker corners
 49 
        // Extract checker corners
48 
        bool success1 = cv::findChessboardCorners(SMCalibrationSetI.frame1, checkerCount, qci1, cv::CALIB_CB_ADAPTIVE_THRESH + cv::CALIB_CB_FAST_CHECK);
 50 
        bool success1 = cv::findChessboardCorners(SMCalibrationSetI.frame1, checkerCount, qci1, cv::CALIB_CB_ADAPTIVE_THRESH + cv::CALIB_CB_FAST_CHECK);
49 
        if(success1){
 51 
        if(success1){
- 
 
 52 
            // Convert bayer to grayscale
50 
            cv::Mat gray;
 53 
            cv::Mat gray;
51 
            cv::cvtColor(SMCalibrationSetI.frame1, gray, CV_RGB2GRAY);
 54 
            cv::cvtColor(SMCalibrationSetI.frame1, gray, CV_BayerBG2GRAY);
52 
            cv::cornerSubPix(gray, qci1, cv::Size(5, 5), cv::Size(-1, -1),cv::TermCriteria(CV_TERMCRIT_EPS + CV_TERMCRIT_ITER, 20, 0.001));
 55 
            cv::cornerSubPix(gray, qci1, cv::Size(5, 5), cv::Size(-1, -1),cv::TermCriteria(CV_TERMCRIT_EPS + CV_TERMCRIT_ITER, 20, 0.001));
53 
            // Draw colored chessboard
 56 
            // Draw colored chessboard
54 
            SMCalibrationSetI.frame1Result = SMCalibrationSetI.frame1.clone();
 57 
            SMCalibrationSetI.frame1Result = SMCalibrationSetI.frame1.clone();
55 
            cvtools::drawChessboardCorners(SMCalibrationSetI.frame1Result, checkerCount, qci1, success1, 10);
 58 
            cvtools::drawChessboardCorners(SMCalibrationSetI.frame1Result, checkerCount, qci1, success1, 10);
56 
        }
 59 
        }
57 
 
 60 
 
58 
        emit newFrameResult(i, 1, success1, SMCalibrationSetI.frame1Result);
 61 
        emit newFrameResult(i, 1, success1, SMCalibrationSetI.frame1Result);
59 
 
 62 
 
60 
        SMCalibrationSetI.success = success0 && success1;
 63 
        SMCalibrationSetI.success = success0 && success1;
61 
 
 64 
 
62 
        // Add to whole set
 65 
        // Add to whole set
63 
        if(SMCalibrationSetI.success){
 66 
        if(SMCalibrationSetI.success){
64 
            qc0.push_back(qci0);
 67 
            qc0.push_back(qci0);
65 
            qc1.push_back(qci1);
 68 
            qc1.push_back(qci1);
66 
            angles.push_back(SMCalibrationSetI.rotationAngle);
 69 
            angles.push_back(SMCalibrationSetI.rotationAngle);
67 
        }
 70 
        }
68 
 
 71 
 
69 
        // Show progress
 72 
        // Show progress
70 
        emit newSetProcessed(i);
 73 
        emit newSetProcessed(i);
71 
    }
 74 
    }
72 
 
 75 
 
73 
    int nValidSets = qc0.size();
 76 
    int nValidSets = qc0.size();
74 
    if(nValidSets < 2){
 77 
    if(nValidSets < 2){
75 
        std::cerr << "Not enough valid calibration sequences!" << std::endl;
 78 
        std::cerr << "Not enough valid calibration sequences!" << std::endl;
76 
        emit done();
 79 
        emit done();
77 
        return;
 80 
        return;
78 
    }
 81 
    }
79 
 
 82 
 
80 
    // Generate world object coordinates [mm]
 83 
    // Generate world object coordinates [mm]
81 
    float checkerSize = settings.value("calibration/checkerSize", 15.0).toFloat(); // width and height of one field in mm
 84 
    float checkerSize = settings.value("calibration/checkerSize", 15.0).toFloat(); // width and height of one field in mm
82 
    std::vector<cv::Point3f> Qi;
 85 
    std::vector<cv::Point3f> Qi;
83 
    for (int h=0; h<checkerCount.height; h++)
 86 
    for (int h=0; h<checkerCount.height; h++)
84 
        for (int w=0; w<checkerCount.width; w++)
 87 
        for (int w=0; w<checkerCount.width; w++)
85 
            Qi.push_back(cv::Point3f(checkerSize * w, checkerSize* h, 0.0));
 88 
            Qi.push_back(cv::Point3f(checkerSize * w, checkerSize* h, 0.0));
86 
    std::vector< std::vector<cv::Point3f> > Q;
 89 
    std::vector< std::vector<cv::Point3f> > Q;
87 
    for(int i=0; i<qc0.size(); i++)
 90 
    for(int i=0; i<qc0.size(); i++)
88 
        Q.push_back(Qi);
 91 
        Q.push_back(Qi);
89 
 
 92 
 
90 
    // calibrate the cameras
 93 
    // calibrate the cameras
91 
    SMCalibrationParameters cal;
 94 
    SMCalibrationParameters cal;
92 
    cal.frameWidth = calibrationData[0].frame0.cols;
 95 
    cal.frameWidth = calibrationData[0].frame0.cols;
93 
    cal.frameHeight = calibrationData[0].frame0.rows;
 96 
    cal.frameHeight = calibrationData[0].frame0.rows;
94 
    cv::Size frameSize(cal.frameWidth, cal.frameHeight);
 97 
    cv::Size frameSize(cal.frameWidth, cal.frameHeight);
95 
 
 98 
 
96 
    // determine only k1, k2 for lens distortion
 99 
    // determine only k1, k2 for lens distortion
97 
    int flags = cv::CALIB_FIX_K3;
 100 
    int flags = cv::CALIB_FIX_K3;
98 
    // Note: several of the output arguments below must be cv::Mat, otherwise segfault
 101 
    // Note: several of the output arguments below must be cv::Mat, otherwise segfault
99 
    std::vector<cv::Mat> cam_rvecs0, cam_tvecs0;
 102 
    std::vector<cv::Mat> cam_rvecs0, cam_tvecs0;
100 
    cal.cam0_error = cv::calibrateCamera(Q, qc0, frameSize, cal.K0, cal.k0, cam_rvecs0, cam_tvecs0, flags);
 103 
    cal.cam0_error = cv::calibrateCamera(Q, qc0, frameSize, cal.K0, cal.k0, cam_rvecs0, cam_tvecs0, flags);
101 
 
 104 
 
102 
    // refine extrinsics for camera 0
 105 
    // refine extrinsics for camera 0
103 
    for(int i=0; i<Q.size(); i++)
 106 
    for(int i=0; i<Q.size(); i++)
104 
        cv::solvePnPRansac(Q[i], qc0[i], cal.K0, cal.k0, cam_rvecs0[i], cam_tvecs0[i], true, 100, 0.05, 100, cv::noArray(), CV_ITERATIVE);
 107 
        cv::solvePnPRansac(Q[i], qc0[i], cal.K0, cal.k0, cam_rvecs0[i], cam_tvecs0[i], true, 100, 0.05, 100, cv::noArray(), CV_ITERATIVE);
105 
 
 108 
 
106 
    std::vector<cv::Mat> cam_rvecs1, cam_tvecs1;
 109 
    std::vector<cv::Mat> cam_rvecs1, cam_tvecs1;
107 
    cal.cam1_error = cv::calibrateCamera(Q, qc1, frameSize, cal.K1, cal.k1, cam_rvecs1, cam_tvecs1, flags);
 110 
    cal.cam1_error = cv::calibrateCamera(Q, qc1, frameSize, cal.K1, cal.k1, cam_rvecs1, cam_tvecs1, flags);
108 
 
 111 
 
109 
    // stereo calibration
 112 
    // stereo calibration
110 
    int flags_stereo = cv::CALIB_USE_INTRINSIC_GUESS + cv::CALIB_FIX_K3;
 113 
    int flags_stereo = cv::CALIB_USE_INTRINSIC_GUESS + cv::CALIB_FIX_K3;
111 
    cv::Mat E, F, R1, T1;
 114 
    cv::Mat E, F, R1, T1;
112 
    cal.stereo_error = cv::stereoCalibrate(Q, qc0, qc1, cal.K0, cal.k0, cal.K1, cal.k1,
 115 
    cal.stereo_error = cv::stereoCalibrate(Q, qc0, qc1, cal.K0, cal.k0, cal.K1, cal.k1,
113 
                                              frameSize, R1, T1, E, F,
 116 
                                              frameSize, R1, T1, E, F,
114 
                                              cv::TermCriteria(cv::TermCriteria::COUNT + cv::TermCriteria::EPS, 50, DBL_EPSILON),
 117 
                                              cv::TermCriteria(cv::TermCriteria::COUNT + cv::TermCriteria::EPS, 50, DBL_EPSILON),
115 
                                              flags_stereo);
 118 
                                              flags_stereo);
116 
 
 119 
 
117 
    cal.R1 = R1;
 120 
    cal.R1 = R1;
118 
    cal.T1 = T1;
 121 
    cal.T1 = T1;
119 
    cal.E = E;
 122 
    cal.E = E;
120 
    cal.F = F;
 123 
    cal.F = F;
121 
 
 124 
 
122 
//    // hand-eye calibration
 125 
//    // hand-eye calibration
123 
//    std::vector<cv::Matx33f> Rc(nValidSets - 1); // rotations/translations of the checkerboard in camera 0 reference frame
 126 
//    std::vector<cv::Matx33f> Rc(nValidSets - 1); // rotations/translations of the checkerboard in camera 0 reference frame
124 
//    std::vector<cv::Vec3f> Tc(nValidSets - 1);
 127 
//    std::vector<cv::Vec3f> Tc(nValidSets - 1);
125 
//    std::vector<cv::Matx33f> Rr(nValidSets - 1); // in rotation stage reference frame
 128 
//    std::vector<cv::Matx33f> Rr(nValidSets - 1); // in rotation stage reference frame
126 
//    std::vector<cv::Vec3f> Tr(nValidSets - 1);
 129 
//    std::vector<cv::Vec3f> Tr(nValidSets - 1);
127 
//    for(int i=0; i<nValidSets-1; i++){
 130 
//    for(int i=0; i<nValidSets-1; i++){
128 
//        // relative transformations in camera
 131 
//        // relative transformations in camera
129 
//        cv::Mat cRw1, cRw2;
 132 
//        cv::Mat cRw1, cRw2;
130 
//        cv::Rodrigues(cam_rvecs0[i], cRw1);
 133 
//        cv::Rodrigues(cam_rvecs0[i], cRw1);
131 
//        cv::Rodrigues(cam_rvecs0[i+1], cRw2);
 134 
//        cv::Rodrigues(cam_rvecs0[i+1], cRw2);
132 
//        cv::Mat cTw1 = cam_tvecs0[i];
 135 
//        cv::Mat cTw1 = cam_tvecs0[i];
133 
//        cv::Mat cTw2 = cam_tvecs0[i+1];
 136 
//        cv::Mat cTw2 = cam_tvecs0[i+1];
134 
//        cv::Mat w1Rc = cRw1.t();
 137 
//        cv::Mat w1Rc = cRw1.t();
135 
//        cv::Mat w1Tc = -cRw1.t()*cTw1;
 138 
//        cv::Mat w1Tc = -cRw1.t()*cTw1;
136 
//        Rc[i] = cv::Mat(cRw2*w1Rc);
 139 
//        Rc[i] = cv::Mat(cRw2*w1Rc);
137 
//        Tc[i] = cv::Mat(cRw2*w1Tc+cTw2);
 140 
//        Tc[i] = cv::Mat(cRw2*w1Tc+cTw2);
138 
 
 141 
 
139 
//        // relative transformations in rotation stage
 142 
//        // relative transformations in rotation stage
140 
//        // we define the rotation axis to be in origo, pointing in positive y direction
 143 
//        // we define the rotation axis to be in origo, pointing in positive y direction
141 
//        float angleRadians = (angles[i+1]-angles[i])/180.0*M_PI;
 144 
//        float angleRadians = (angles[i+1]-angles[i])/180.0*M_PI;
142 
//        cv::Vec3f rot_rvec(0.0, -angleRadians, 0.0);
 145 
//        cv::Vec3f rot_rvec(0.0, -angleRadians, 0.0);
143 
//        cv::Mat Rri;
 146 
//        cv::Mat Rri;
144 
//        cv::Rodrigues(rot_rvec, Rri);
 147 
//        cv::Rodrigues(rot_rvec, Rri);
145 
//        Rr[i] = Rri;
 148 
//        Rr[i] = Rri;
146 
//        Tr[i] = 0.0;
 149 
//        Tr[i] = 0.0;
147 
 
 150 
 
148 
////        std::cout << i << std::endl;
 151 
////        std::cout << i << std::endl;
149 
////        std::cout << "cTw1" << cTw1 << std::endl;
 152 
////        std::cout << "cTw1" << cTw1 << std::endl;
150 
////        std::cout << "cTw2" << cTw2 << std::endl;
 153 
////        std::cout << "cTw2" << cTw2 << std::endl;
151 
////        std::cout << "w2Rc" << w2Rc << std::endl;
 154 
////        std::cout << "w2Rc" << w2Rc << std::endl;
152 
////        std::cout << "w2Tc" << w2Tc << std::endl;
 155 
////        std::cout << "w2Tc" << w2Tc << std::endl;
153 
 
 156 
 
154 
////        std::cout << "w2Rc" << w2Rc << std::endl;
 157 
////        std::cout << "w2Rc" << w2Rc << std::endl;
155 
////        std::cout << "w2Tc" << w2Tc << std::endl;
 158 
////        std::cout << "w2Tc" << w2Tc << std::endl;
156 
 
 159 
 
157 
////        cv::Mat Rci;
 160 
////        cv::Mat Rci;
158 
////        cv::Rodrigues(Rc[i], Rci);
 161 
////        cv::Rodrigues(Rc[i], Rci);
159 
////        std::cout << "Rci" << Rci << std::endl;
 162 
////        std::cout << "Rci" << Rci << std::endl;
160 
////        std::cout << "Tc[i]" << Tc[i] << std::endl;
 163 
////        std::cout << "Tc[i]" << Tc[i] << std::endl;
161 
 
 164 
 
162 
////        std::cout << "rot_rvec" << rot_rvec << std::endl;
 165 
////        std::cout << "rot_rvec" << rot_rvec << std::endl;
163 
////        std::cout << "Tr[i]" << Tr[i] << std::endl;
 166 
////        std::cout << "Tr[i]" << Tr[i] << std::endl;
164 
////        std::cout << std::endl;
 167 
////        std::cout << std::endl;
165 
//    }
 168 
//    }
166 
 
 169 
 
167 
//    // determine the transformation from rotation stage to camera 0
 170 
//    // determine the transformation from rotation stage to camera 0
168 
//    cvtools::handEyeCalibrationTsai(Rc, Tc, Rr, Tr, cal.Rr, cal.Tr);
 171 
//    cvtools::handEyeCalibrationTsai(Rc, Tc, Rr, Tr, cal.Rr, cal.Tr);
169 
 
 172 
 
170 
//    for(int i=0; i<nValidSets-1; i++){
 173 
//    for(int i=0; i<nValidSets-1; i++){
171 
//        std::cout << i << std::endl;
 174 
//        std::cout << i << std::endl;
172 
 
 175 
 
173 
//        cv::Mat Rci;
 176 
//        cv::Mat Rci;
174 
//        cv::Rodrigues(Rc[i], Rci);
 177 
//        cv::Rodrigues(Rc[i], Rci);
175 
//        std::cout << "Rc[i]" << Rci << std::endl;
 178 
//        std::cout << "Rc[i]" << Rci << std::endl;
176 
//        std::cout << "Tc[i]" << Tc[i] << std::endl;
 179 
//        std::cout << "Tc[i]" << Tc[i] << std::endl;
177 
 
 180 
 
178 
//        cv::Mat Rri;
 181 
//        cv::Mat Rri;
179 
//        cv::Rodrigues(Rr[i], Rri);
 182 
//        cv::Rodrigues(Rr[i], Rri);
180 
//        std::cout << "Rr[i]" << Rri << std::endl;
 183 
//        std::cout << "Rr[i]" << Rri << std::endl;
181 
//        std::cout << "Tr[i]" << Tr[i] << std::endl;
 184 
//        std::cout << "Tr[i]" << Tr[i] << std::endl;
182 
 
 185 
 
183 
//        cv::Mat Rcr = cv::Mat(cal.Rr)*cv::Mat(Rc[i])*cv::Mat(cal.Rr.t());
 186 
//        cv::Mat Rcr = cv::Mat(cal.Rr)*cv::Mat(Rc[i])*cv::Mat(cal.Rr.t());
184 
//        cv::Rodrigues(Rcr, Rcr);
 187 
//        cv::Rodrigues(Rcr, Rcr);
185 
//        cv::Mat Tcr = -cv::Mat(cal.Rr)*cv::Mat(Rc[i])*cv::Mat(cal.Rr.t())*cv::Mat(cal.Tr) + cv::Mat(cal.Rr)*cv::Mat(Tc[i]) + cv::Mat(cal.Tr);
 188 
//        cv::Mat Tcr = -cv::Mat(cal.Rr)*cv::Mat(Rc[i])*cv::Mat(cal.Rr.t())*cv::Mat(cal.Tr) + cv::Mat(cal.Rr)*cv::Mat(Tc[i]) + cv::Mat(cal.Tr);
186 
//        std::cout << "Rcr[i]" << Rcr << std::endl;
 189 
//        std::cout << "Rcr[i]" << Rcr << std::endl;
187 
//        std::cout << "Tcr[i]" << Tcr << std::endl;
 190 
//        std::cout << "Tcr[i]" << Tcr << std::endl;
188 
//        std::cout << std::endl;
 191 
//        std::cout << std::endl;
189 
//    }
 192 
//    }
190 
 
 193 
 
191 
 
 194 
 
192 
    // Direct rotation axis calibration //
 195 
    // Direct rotation axis calibration //
193 
    // full camera matrices
 196 
    // full camera matrices
194 
    cv::Matx34f P0 = cv::Matx34f::eye();
 197 
    cv::Matx34f P0 = cv::Matx34f::eye();
195 
    cv::Mat RT1(3, 4, CV_32F);
 198 
    cv::Mat RT1(3, 4, CV_32F);
196 
    cv::Mat(cal.R1).copyTo(RT1(cv::Range(0, 3), cv::Range(0, 3)));
 199 
    cv::Mat(cal.R1).copyTo(RT1(cv::Range(0, 3), cv::Range(0, 3)));
197 
    cv::Mat(cal.T1).copyTo(RT1(cv::Range(0, 3), cv::Range(3, 4)));
 200 
    cv::Mat(cal.T1).copyTo(RT1(cv::Range(0, 3), cv::Range(3, 4)));
198 
    cv::Matx34f P1 = cv::Matx34f(RT1);
 201 
    cv::Matx34f P1 = cv::Matx34f(RT1);
199 
 
 202 
 
200 
    // calibration points in camera 0 frame
 203 
    // calibration points in camera 0 frame
201 
    std::vector< std::vector<cv::Point3f> > Qcam;
 204 
    std::vector< std::vector<cv::Point3f> > Qcam;
202 
 
 205 
 
203 
    for(int i=0; i<nValidSets; i++){
 206 
    for(int i=0; i<nValidSets; i++){
204 
        std::vector<cv::Point2f> qc0i, qc1i;
 207 
        std::vector<cv::Point2f> qc0i, qc1i;
205 
 
 208 
 
206 
        cv::undistortPoints(qc0[i], qc0i, cal.K0, cal.k0);
 209 
        cv::undistortPoints(qc0[i], qc0i, cal.K0, cal.k0);
207 
        cv::undistortPoints(qc1[i], qc1i, cal.K1, cal.k1);
 210 
        cv::undistortPoints(qc1[i], qc1i, cal.K1, cal.k1);
208 
//        qc0i = qc0[i];
 211 
//        qc0i = qc0[i];
209 
//        qc1i = qc1[i];
 212 
//        qc1i = qc1[i];
210 
 
 213 
 
211 
        cv::Mat Qhom, Qcami;
 214 
        cv::Mat Qhom, Qcami;
212 
        cv::triangulatePoints(P0, P1, qc0i, qc1i, Qhom);
 215 
        cv::triangulatePoints(P0, P1, qc0i, qc1i, Qhom);
213 
        cvtools::convertMatFromHomogeneous(Qhom, Qcami);
 216 
        cvtools::convertMatFromHomogeneous(Qhom, Qcami);
214 
        std::vector<cv::Point3f> QcamiPoints;
 217 
        std::vector<cv::Point3f> QcamiPoints;
215 
        cvtools::matToPoints3f(Qcami, QcamiPoints);
 218 
        cvtools::matToPoints3f(Qcami, QcamiPoints);
216 
 
 219 
 
217 
        Qcam.push_back(QcamiPoints);
 220 
        Qcam.push_back(QcamiPoints);
218 
    }
 221 
    }
219 
 
 222 
 
220 
    cv::Vec3f axis, point;
 223 
    cv::Vec3f axis, point;
221 
    cvtools::rotationAxisCalibration(Qcam, Qi, axis, point);
 224 
    cvtools::rotationAxisCalibration(Qcam, Qi, axis, point);
222 
 
 225 
 
223 
    // construct transformation matrix
 226 
    // construct transformation matrix
224 
    cv::Vec3f ex = axis.cross(cv::Vec3f(0,0,1.0));
 227 
    cv::Vec3f ex = axis.cross(cv::Vec3f(0,0,1.0));
225 
    ex = cv::normalize(ex);
 228 
    ex = cv::normalize(ex);
226 
    cv::Vec3f ez = ex.cross(axis);
 229 
    cv::Vec3f ez = ex.cross(axis);
227 
    ez = cv::normalize(ez);
 230 
    ez = cv::normalize(ez);
228 
 
 231 
 
229 
    cv::Mat RrMat(3, 3, CV_32F);
 232 
    cv::Mat RrMat(3, 3, CV_32F);
230 
    cv::Mat(ex).copyTo(RrMat.col(0));
 233 
    cv::Mat(ex).copyTo(RrMat.col(0));
231 
    cv::Mat(axis).copyTo(RrMat.col(1));
 234 
    cv::Mat(axis).copyTo(RrMat.col(1));
232 
    cv::Mat(ez).copyTo(RrMat.col(2));
 235 
    cv::Mat(ez).copyTo(RrMat.col(2));
233 
 
 236 
 
234 
    cal.Rr = cv::Matx33f(RrMat).t();
 237 
    cal.Rr = cv::Matx33f(RrMat).t();
235 
    cal.Tr = -cv::Matx33f(RrMat).t()*point;
 238 
    cal.Tr = -cv::Matx33f(RrMat).t()*point;
236 
 
 239 
 
237 
    // Print to std::cout
 240 
    // Print to std::cout
238 
    cal.print();
 241 
    cal.print();
239 
 
 242 
 
240 
    // save to (reentrant qsettings object)
 243 
    // save to (reentrant qsettings object)
241 
    settings.setValue("calibration/parameters", QVariant::fromValue(cal));
 244 
    settings.setValue("calibration/parameters", QVariant::fromValue(cal));
242 
 
 245 
 
243 
    emit done();
 246 
    emit done();
244 
 
 247 
 
245 
}
 248 
}
246 
 
 249