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181 jakw 1 
//
2 
// Two Frequency Phase Shifting using the Heterodyne Principle
3 
//
4 
// This implementation follows "Reich, Ritter, Thesing, White light heterodyne principle for 3D-measurement", SPIE (1997)
5 
// Different from the paper, it uses only two different frequencies.
6 
//
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// The number of periods in the primary frequency can be chosen freely, but small changes can have a considerable impact on quality.
181 jakw 8 
// The number of phase shifts can be chosen freely (min. 3), and higher values reduce the effects of image noise. They also allow us to filter bad points based on energy at non-primary frequencies.
9 
//
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#include "AlgorithmPhaseShiftTwoFreq.h"
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#include <math.h>
13 
 
14 
#include "cvtools.h"
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#include "algorithmtools.h"
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17 
#ifndef M_PI
18 
    #define M_PI 3.14159265358979323846
19 
#endif
20 
 
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static unsigned int nStepsPrimary = 16; // number of shifts/steps in primary
22 
static unsigned int nStepsSecondary = 8; // number of shifts/steps in secondary
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static float nPeriodsPrimary = 48; // primary period
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128 jakw 25 
AlgorithmPhaseShiftTwoFreq::AlgorithmPhaseShiftTwoFreq(unsigned int _screenCols, unsigned int _screenRows) : Algorithm(_screenCols, _screenRows){
4 jakw 26 
 
72 jakw 27 
    // Set N
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    N = 2+nStepsPrimary+nStepsSecondary;
72 jakw 29 
 
74 jakw 30 
    // Determine the secondary (wider) period
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    float nPeriodsSecondary = (screenCols*nPeriodsPrimary)/(screenCols-nPeriodsPrimary);
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70 jakw 33 
    // all on pattern
34 
    cv::Mat allOn(1, screenCols, CV_8UC3, cv::Scalar::all(255));
35 
    patterns.push_back(allOn);
36 
 
37 
    // all off pattern
38 
    cv::Mat allOff(1, screenCols, CV_8UC3, cv::Scalar::all(0));
39 
    patterns.push_back(allOff);
40 
 
4 jakw 41 
    // Precompute encoded patterns
42 
    const float pi = M_PI;
43 
 
74 jakw 44 
    // Primary encoding patterns
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    for(unsigned int i=0; i<nStepsPrimary; i++){
46 
        float phase = 2.0*pi/nStepsPrimary * i;
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        float pitch = nPeriodsPrimary;
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        cv::Mat patternI(1,1,CV_8U);
49 
        patternI = computePhaseVector(screenCols, phase, pitch);
50 
        patterns.push_back(patternI.t());
51 
    }
4 jakw 52 
 
74 jakw 53 
    // Secondary encoding patterns
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    for(unsigned int i=0; i<nStepsSecondary; i++){
55 
        float phase = 2.0*pi/nStepsSecondary * i;
182 jakw 56 
        float pitch = nPeriodsSecondary;
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        cv::Mat patternI(1,1,CV_8U);
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        patternI = computePhaseVector(screenCols, phase, pitch);
59 
        patterns.push_back(patternI.t());
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    }
61 
 
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4 jakw 63 
}
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cv::Mat AlgorithmPhaseShiftTwoFreq::getEncodingPattern(unsigned int depth){
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    return patterns[depth];
67 
}
68 
 
128 jakw 69 
void AlgorithmPhaseShiftTwoFreq::get3DPoints(SMCalibrationParameters calibration, const std::vector<cv::Mat>& frames0, const std::vector<cv::Mat>& frames1, std::vector<cv::Point3f>& Q, std::vector<cv::Vec3b>& color){
4 jakw 70 
 
70 jakw 71 
    const float pi = M_PI;
72 
 
73 
    assert(frames0.size() == N);
74 
    assert(frames1.size() == N);
75 
 
76 
    int frameRows = frames0[0].rows;
77 
    int frameCols = frames0[0].cols;
78 
 
178 jakw 79 
    // Rectifying homographies (rotation+projections)
80 
    cv::Size frameSize(frameCols, frameRows);
81 
    cv::Mat R, T;
82 
    // stereoRectify segfaults unless R is double precision
83 
    cv::Mat(calibration.R1).convertTo(R, CV_64F);
84 
    cv::Mat(calibration.T1).convertTo(T, CV_64F);
85 
    cv::Mat R0, R1, P0, P1, QRect;
86 
    cv::stereoRectify(calibration.K0, calibration.k0, calibration.K1, calibration.k1, frameSize, R, T, R0, R1, P0, P1, QRect, 0);
87 
 
88 
    // Interpolation maps (lens distortion and rectification)
89 
    cv::Mat map0X, map0Y, map1X, map1Y;
90 
    cv::initUndistortRectifyMap(calibration.K0, calibration.k0, R0, P0, frameSize, CV_32F, map0X, map0Y);
91 
    cv::initUndistortRectifyMap(calibration.K1, calibration.k1, R1, P1, frameSize, CV_32F, map1X, map1Y);
92 
 
182 jakw 93 
    int frameRectRows = map0X.rows;
94 
    int frameRectCols = map0X.cols;
95 
 
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    // Gray-scale and remap
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    std::vector<cv::Mat> frames0Rect(N);
98 
    std::vector<cv::Mat> frames1Rect(N);
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    for(unsigned int i=0; i<N; i++){
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        cv::Mat temp;
101 
        cv::cvtColor(frames0[i], temp, CV_BayerBG2GRAY);
102 
        cv::remap(temp, frames0Rect[i], map0X, map0Y, CV_INTER_LINEAR);
103 
        cv::cvtColor(frames1[i], temp, CV_BayerBG2GRAY);
104 
        cv::remap(temp, frames1Rect[i], map1X, map1Y, CV_INTER_LINEAR);
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    }
106 
 
107 
    // Decode camera0
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    std::vector<cv::Mat> frames0Primary(frames0Rect.begin()+2, frames0Rect.begin()+2+nStepsPrimary);
109 
    std::vector<cv::Mat> frames0Secondary(frames0Rect.begin()+2+nStepsPrimary, frames0Rect.end());
182 jakw 110 
 
76 jakw 111 
    std::vector<cv::Mat> F0Primary = getDFTComponents(frames0Primary);
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    cv::Mat up0Primary;
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    cv::phase(F0Primary[2], -F0Primary[3], up0Primary);
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76 jakw 115 
    std::vector<cv::Mat> F0Secondary = getDFTComponents(frames0Secondary);
116 
    cv::Mat up0Secondary;
117 
    cv::phase(F0Secondary[2], -F0Secondary[3], up0Secondary);
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74 jakw 119 
    cv::Mat up0Equivalent = up0Primary - up0Secondary;
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    up0Equivalent = cvtools::modulo(up0Equivalent, 2.0*pi);
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    cv::Mat up0 = unwrapWithCue(up0Primary, up0Equivalent, (float)screenCols/nPeriodsPrimary);
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    up0 *= screenCols/(2.0*pi);
123 
    cv::Mat amplitude0;
124 
    cv::magnitude(F0Primary[2], -F0Primary[3], amplitude0);
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182 jakw 126 
    // Collected signal energy at higher frequencies
127 
    cv::Mat energy0Primary(frameRectRows, frameRectCols, CV_32F, cv::Scalar(0.0));
128 
    for(unsigned int i=0; i<nStepsPrimary-1; i++){
129 
        cv::Mat magnitude;
130 
        cv::magnitude(F0Primary[i*2 + 2], F0Primary[i*2 + 3], magnitude);
131 
        cv::add(energy0Primary, magnitude, energy0Primary, cv::noArray(), CV_32F);
132 
    }
133 
 
134 
    cv::Mat energy0Secondary(frameRectRows, frameRectCols, CV_32F, cv::Scalar(0.0));
135 
    for(unsigned int i=0; i<nStepsSecondary-1; i++){
136 
        cv::Mat magnitude;
137 
        cv::magnitude(F0Secondary[i*2 + 2], F0Secondary[i*2 + 3], magnitude);
138 
        cv::add(energy0Secondary, magnitude, energy0Secondary, cv::noArray(), CV_32F);
139 
    }
140 
 
185 jakw 141 
    #ifdef QT_DEBUG
142 
        cvtools::writeMat(up0Primary, "up0Primary.mat", "up0Primary");
143 
        cvtools::writeMat(up0Secondary, "up0Secondary.mat", "up0Secondary");
144 
        cvtools::writeMat(up0Equivalent, "up0Equivalent.mat", "up0Equivalent");
145 
        cvtools::writeMat(up0, "up0.mat", "up0");
146 
        cvtools::writeMat(amplitude0, "amplitude0.mat", "amplitude0");
147 
        cvtools::writeMat(energy0Primary, "energy0Primary.mat", "energy0Primary");
148 
        cvtools::writeMat(energy0Secondary, "energy0Secondary.mat", "energy0Secondary");
149 
    #endif
150 
 
70 jakw 151 
    // Decode camera1
178 jakw 152 
    std::vector<cv::Mat> frames1Primary(frames1Rect.begin()+2, frames1Rect.begin()+2+nStepsPrimary);
153 
    std::vector<cv::Mat> frames1Secondary(frames1Rect.begin()+2+nStepsPrimary, frames1Rect.end());
182 jakw 154 
 
76 jakw 155 
    std::vector<cv::Mat> F1Primary = getDFTComponents(frames1Primary);
74 jakw 156 
    cv::Mat up1Primary;
76 jakw 157 
    cv::phase(F1Primary[2], -F1Primary[3], up1Primary);
182 jakw 158 
 
76 jakw 159 
    std::vector<cv::Mat> F1Secondary = getDFTComponents(frames1Secondary);
160 
    cv::Mat up1Secondary;
161 
    cv::phase(F1Secondary[2], -F1Secondary[3], up1Secondary);
182 jakw 162 
 
74 jakw 163 
    cv::Mat up1Equivalent = up1Primary - up1Secondary;
128 jakw 164 
    up1Equivalent = cvtools::modulo(up1Equivalent, 2.0*pi);
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    cv::Mat up1 = unwrapWithCue(up1Primary, up1Equivalent, (float)screenCols/nPeriodsPrimary);
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    up1 *= screenCols/(2.0*pi);
167 
    cv::Mat amplitude1;
168 
    cv::magnitude(F1Primary[2], -F1Primary[3], amplitude1);
70 jakw 169 
 
182 jakw 170 
    // Collected signal energy at higher frequencies
171 
    cv::Mat energy1Primary(frameRectRows, frameRectCols, CV_32F, cv::Scalar(0.0));
172 
    for(unsigned int i=0; i<nStepsPrimary-1; i++){
173 
        cv::Mat magnitude;
174 
        cv::magnitude(F1Primary[i*2 + 2], F1Primary[i*2 + 3], magnitude);
175 
        cv::add(energy1Primary, magnitude, energy1Primary, cv::noArray(), CV_32F);
176 
    }
177 
 
178 
    cv::Mat energy1Secondary(frameRectRows, frameRectCols, CV_32F, cv::Scalar(0.0));
179 
    for(unsigned int i=0; i<nStepsSecondary-1; i++){
180 
        cv::Mat magnitude;
181 
        cv::magnitude(F1Secondary[i*2 + 2], F1Secondary[i*2 + 3], magnitude);
182 
        cv::add(energy1Secondary, magnitude, energy1Secondary, cv::noArray(), CV_32F);
183 
    }
184 
 
185 jakw 185 
    #ifdef QT_DEBUG
186 
        cvtools::writeMat(up1, "up1.mat", "up1");
187 
    #endif
188 
 
118 jakw 189 
    // color debayer and remap
178 jakw 190 
    cv::Mat color0, color1;
191 
    cv::cvtColor(frames0[0], color0, CV_BayerBG2RGB);
192 
    cv::remap(color0, color0, map0X, map0Y, CV_INTER_LINEAR);
70 jakw 193 
 
178 jakw 194 
    cv::cvtColor(frames1[0], color1, CV_BayerBG2RGB);
195 
    cv::remap(color1, color1, map1X, map1Y, CV_INTER_LINEAR);
118 jakw 196 
 
185 jakw 197 
    #ifdef QT_DEBUG
182 jakw 198 
        cvtools::writeMat(color0, "color0.mat", "color0");
199 
        cvtools::writeMat(color1, "color1.mat", "color1");
200 
    #endif
118 jakw 201 
 
70 jakw 202 
    // Occlusion masks
178 jakw 203 
    cv::Mat occlusion0, occlusion1;
204 
    cv::subtract(frames0Rect[0], frames0Rect[1], occlusion0);
205 
    occlusion0 = (occlusion0 > 25) & (occlusion0 < 250);
206 
    cv::subtract(frames1Rect[0], frames1Rect[1], occlusion1);
207 
    occlusion1 = (occlusion1 > 25) & (occlusion1 < 250);
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128 jakw 209 
    // Threshold on energy at primary frequency
178 jakw 210 
    occlusion0 = occlusion0 & (amplitude0 > 5.0*nStepsPrimary);
211 
    occlusion1 = occlusion1 & (amplitude1 > 5.0*nStepsPrimary);
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182 jakw 213 
    // Threshold on energy ratios
214 
    occlusion0 = occlusion0 & (amplitude0 > 0.85*energy0Primary);
215 
    occlusion0 = occlusion0 & (amplitude0 > 0.85*energy0Secondary);
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182 jakw 217 
    occlusion1 = occlusion1 & (amplitude1 > 0.85*energy1Primary);
218 
    occlusion1 = occlusion1 & (amplitude1 > 0.85*energy1Secondary);
70 jakw 219 
 
182 jakw 220 
//    // Erode occlusion masks
221 
//    cv::Mat strel = cv::getStructuringElement(cv::MORPH_ELLIPSE, cv::Size(5,5));
222 
//    cv::erode(occlusion0, occlusion0, strel);
223 
//    cv::erode(occlusion1, occlusion1, strel);
71 jakw 224 
 
182 jakw 225 
//    // Threshold on gradient of phase
226 
//    cv::Mat edges0;
227 
//    cv::Sobel(up0, edges0, -1, 1, 1, 5);
228 
//    occlusion0 = occlusion0 & (abs(edges0) < 150);
71 jakw 229 
 
182 jakw 230 
//    cv::Mat edges1;
231 
//    cv::Sobel(up1, edges1, -1, 1, 1, 5);
232 
//    occlusion1 = occlusion1 & (abs(edges1) < 150);
71 jakw 233 
 
185 jakw 234 
    #ifdef QT_DEBUG
235 
        cvtools::writeMat(occlusion0, "occlusion0.mat", "occlusion0");
182 jakw 236 
        cvtools::writeMat(occlusion1, "occlusion1.mat", "occlusion1");
237 
    #endif
238 
 
70 jakw 239 
    // Match phase maps
240 
 
241 
    // camera0 against camera1
178 jakw 242 
    std::vector<cv::Vec2f> q0, q1;
70 jakw 243 
    for(int row=0; row<frameRectRows; row++){
244 
        for(int col=0; col<frameRectCols; col++){
245 
 
178 jakw 246 
            if(!occlusion0.at<char>(row,col))
70 jakw 247 
                continue;
248 
 
178 jakw 249 
            float up0i = up0.at<float>(row,col);
250 
            for(int col1=0; col1<up1.cols-1; col1++){
70 jakw 251 
 
178 jakw 252 
                if(!occlusion1.at<char>(row,col1) || !occlusion1.at<char>(row,col1+1))
70 jakw 253 
                    continue;
254 
 
178 jakw 255 
                float up1Left = up1.at<float>(row,col1);
256 
                float up1Right = up1.at<float>(row,col1+1);
70 jakw 257 
 
74 jakw 258 
                if((up1Left <= up0i) && (up0i <= up1Right) && (up0i-up1Left < 1) && (up1Right-up0i < 1)){
70 jakw 259 
 
260 
                    float col1i = col1 + (up0i-up1Left)/(up1Right-up1Left);
261 
 
178 jakw 262 
                    q0.push_back(cv::Point2f(col, row));
263 
                    q1.push_back(cv::Point2f(col1i, row));
71 jakw 264 
 
265 
                    break;
70 jakw 266 
                }
267 
            }
268 
        }
269 
    }
270 
 
271 
 
178 jakw 272 
    int nMatches = q0.size();
74 jakw 273 
 
70 jakw 274 
    if(nMatches < 1){
275 
        Q.resize(0);
276 
        color.resize(0);
277 
 
278 
        return;
279 
    }
280 
 
281 
    // Retrieve color information
282 
    color.resize(nMatches);
283 
    for(int i=0; i<nMatches; i++){
284 
 
178 jakw 285 
        cv::Vec3b c0 = color0.at<cv::Vec3b>(q0[i][1], q0[i][0]);
286 
        cv::Vec3b c1 = color1.at<cv::Vec3b>(q1[i][1], q1[i][0]);
70 jakw 287 
 
288 
        color[i] = 0.5*c0 + 0.5*c1;
289 
    }
290 
 
291 
    // Triangulate points
292 
    cv::Mat QMatHomogenous, QMat;
178 jakw 293 
    cv::triangulatePoints(P0, P1, q0, q1, QMatHomogenous);
70 jakw 294 
    cvtools::convertMatFromHomogeneous(QMatHomogenous, QMat);
295 
 
296 
    // Undo rectification
297 
    cv::Mat R0Inv;
298 
    cv::Mat(R0.t()).convertTo(R0Inv, CV_32F);
299 
    QMat = R0Inv*QMat;
300 
 
301 
    cvtools::matToPoints3f(QMat, Q);
302 
 
4 jakw 303 
}