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00021 #include "opencv2/imgproc/imgproc.hpp"
00022 #include <opencv/cv.h>
00023 #include <numeric>
00024 #include <tuw_ellipses/ellipses.h>
00025 #include <tuw_ellipses/ellipses_defaults.h>
00026 #include <boost/foreach.hpp>
00027 #include "tuw_utils/canny.h"
00028 #include "tuw_utils/ellipse_refinement.h"
00029
00030 using namespace tuw;
00031
00032
00033 EllipsesDetection::~EllipsesDetection()
00034 {
00035 if(param_ != NULL) delete param_;
00036 }
00037
00038 EllipsesDetection::EllipsesDetection(Parameters *param)
00039 :param_(param), loop_count(0) {
00040 }
00041
00042 void EllipsesDetection::createEllipseCanditates () {
00043 ellipses_.clear();
00044 ellipses_.resize(contours_.size());
00045 cv::Mat cameraMatrix, distCoeffs;
00046 for(unsigned int i = 0; i < contours_.size(); i++) {
00047 unsigned int count = contours_[i].size();
00048 Ellipse &ellipse = ellipses_[i];
00049 ellipse.init();
00050 ellipse.id = i;
00051 if(param_->filter_convex) {
00052 cv::approxPolyDP( cv::Mat (contours_[i]), *ellipse.polygon, param_->threshold_polygon, true );
00053 ellipse.boxContour = cv::boundingRect( cv::Mat(*ellipse.polygon) );
00054
00055 }
00056 ellipse.contourDistort->resize(count);
00057 ellipse.contourUndistort->resize(count);
00058 for(unsigned int j = 0; j < count; j++) {
00059 (*ellipse.contourDistort)[j] = contours_[i][j];
00060 (*ellipse.contourUndistort)[j] = contours_[i][j];
00061 }
00062 if(param_->distorted_input) {
00063 cv::undistortPoints(*ellipse.contourDistort, *ellipse.contourUndistort, camera_.cameraMatrix, camera_.distCoeffs, cv::Mat(), camera_.projectionMatrix);
00064 }
00065 }
00066 }
00067
00068
00069 EllipsesDetection::DetectionState EllipsesDetection::filterContour (Ellipse &ellipse) {
00070 if(ellipse.contourDistort->size() < param_->threshold_contour_min_points) {
00071 ellipse.detection = INVALID_CONTOUR_POINTS;
00072 return ellipse.detection;
00073 }
00074 if(param_->filter_convex && !cv::isContourConvex(*ellipse.polygon)) {
00075 ellipse.detection = INVALID_CONTOUR_CONVEX;
00076 return ellipse.detection;
00077 }
00078 return ellipse.detection;
00079 }
00080
00081 void EllipsesDetection::edge_detection(const cv::Mat &m) {
00082 imgGray_ = m;
00083 switch(param_->edge_detection) {
00084 case EDGE_DETECTION_THRESHOLD:
00085 imgEdges_ = m >= param_->threshold_edge_detection1;
00086 break;
00087 case EDGE_DETECTION_CANNY:
00088 cv::blur(imgGray_, imgBlured_, cv::Size(3,3) );
00089 tuw::Canny(imgBlured_, imgEdges_, imgGradient_, imgDirection_, imgSobelDx_, imgSobelDy_, param_->threshold_edge_detection1, param_->threshold_edge_detection2, param_->kernel_size_edge_detection);
00090 break;
00091 }
00092 }
00093
00094 void EllipsesDetection::contour_detection() {
00095 switch(param_->edge_linking) {
00096 case EDGE_LINKING_OPENCV_APPROX_NONE:
00097 cv::findContours ( imgEdges_, contours_, CV_RETR_LIST, CV_CHAIN_APPROX_NONE );
00098 break;
00099 case EDGE_LINKING_OPENCV_APPROX_SIMPLE:
00100 cv::findContours( imgEdges_, contours_, CV_RETR_LIST, CV_CHAIN_APPROX_SIMPLE );
00101 break;
00102 case EDGE_LINKING_TUW_SIMPLE:
00103 if(param_->edge_detection != EDGE_DETECTION_CANNY) break;
00104 contour_detector_.Init(imgGray_.cols, imgGray_.rows);
00105 contour_detector_.Perform(imgEdges_.data, tuw::Contour::MODE_SIMPLE, imgGradient_.data);
00106 contour_detector_.getContours(contours_);
00107 break;
00108 case EDGE_LINKING_TUW_COMPLEX:
00109 if(param_->edge_detection != EDGE_DETECTION_CANNY) break;
00110 contour_detector_.Init(imgGray_.cols, imgGray_.rows);
00111 contour_detector_.Perform(imgEdges_.data, tuw::Contour::MODE_COMPLEX, imgGradient_.data);
00112 contour_detector_.getContours(contours_);
00113 break;
00114 case EDGE_LINKING_TUW_CONTOUR:
00115 if(param_->edge_detection != EDGE_DETECTION_CANNY) break;
00116 contour_detector_.Init(imgGray_.cols, imgGray_.rows);
00117 contour_detector_.Perform(imgEdges_.data, tuw::Contour::MODE_CONTOUR, imgGradient_.data);
00118 contour_detector_.getContours(contours_);
00119 break;
00120 }
00121 }
00122
00123 void EllipsesDetection::fit_ellipses_opencv (const cv::Mat &m, const cv::Mat cameraMatrix, const cv::Mat distCoeffs, const cv::Mat projectionMatrix, const boost::posix_time::ptime &tstamp) {
00124 loop_count++;
00125 tstamp_ = tstamp;
00126 if(param_->distorted_input) {
00127 cameraMatrix.convertTo(camera_.cameraMatrix, CV_64F) ;
00128 distCoeffs.convertTo(camera_.distCoeffs, CV_64F) ;
00129 projectionMatrix(cv::Rect(0,0,3,3)).convertTo(camera_.projectionMatrix, CV_64F) ;
00130 camera_.projectionMatrix(1,1) = camera_.projectionMatrix(0,0);
00131 } else {
00132 projectionMatrix(cv::Rect(0,0,3,3)).convertTo(camera_.cameraMatrix, CV_64F) ;
00133 camera_.distCoeffs = (cv::Mat_<double>(1,5) << 0, 0, 0, 0, 0);
00134 projectionMatrix(cv::Rect(0,0,3,3)).convertTo(camera_.projectionMatrix, CV_64F) ;
00135 }
00136
00137 edge_detection(m);
00138 contour_detection();
00139 createEllipseCanditates();
00140
00141 double min_radius = m.rows * param_->threshold_min_radius;
00142 double max_radius = m.rows * param_->threshold_max_radius;
00143
00144 for(unsigned int i = 0; i < ellipses_.size(); i++) {
00145 Ellipse &ellipse = ellipses_[i];
00146 if(filterContour (ellipse) != VALID) continue;
00147 cv::Mat pointsf(*ellipse.contourUndistort);
00148 ellipse.boxEllipse = fitEllipse ( pointsf );
00149 ellipse.radiusEllipseMax = MAX( ellipse.boxEllipse.size.width , ellipse.boxEllipse.size.height) / 2.0;
00150 ellipse.radiusEllipseMin = MIN( ellipse.boxEllipse.size.width , ellipse.boxEllipse.size.height) / 2.0;
00151 if(ellipse.radiusEllipseMax < min_radius) {
00152 ellipse.detection = INVALID_MIN_RAIDUS;
00153 }
00154 if(ellipse.radiusEllipseMax > max_radius) {
00155 ellipse.detection = INVALID_MAX_RAIDUS;
00156 }
00157 if(filterEllipse (ellipse) != VALID) continue;
00158 if(filterContourMean(ellipse) != VALID) continue;
00159 }
00160 if(param_->ellipse_redefinement &&!imgSobelDx_.empty() && !imgSobelDy_.empty()) {
00161 for(unsigned int i = 0; i < ellipses_.size(); i++) {
00162 EllipseRedefinement(ellipses_[i]);
00163 }
00164 }
00165 }
00166
00167 tuw::EllipseRefinement ellipseRefinementDual;
00168
00169 EllipsesDetection::DetectionState EllipsesDetection::EllipseRedefinement(Ellipse &ellipse) {
00170 if(ellipse.detection != VALID) return ellipse.detection;
00171
00172 tuw::EllipseRefinement::Ellipse e;
00173 e.setEllipse(ellipse.boxEllipse);
00174 ellipseRefinementDual.refine(imgSobelDx_, imgSobelDy_, *ellipse.contourUndistort, e);
00175 e.get(ellipse.boxEllipse);
00176 return ellipse.detection;
00177 }
00178
00179
00180 EllipsesDetection::DetectionState EllipsesDetection::filterEllipse(Ellipse &ellipse) {
00181 if(ellipse.detection != VALID) return ellipse.detection;
00182 double boxEllipseRatio = ellipse.radiusEllipseMin / ellipse.radiusEllipseMax;
00183 if ( boxEllipseRatio < param_->threshold_ring_ratio ) {
00184 ellipse.detection = INVALID_ROTATED_RECT_RATIO;
00185 return ellipse.detection;
00186 }
00187 return ellipse.detection;
00188 }
00189
00190 void EllipsesDetection::createRings() {
00191 if(!param_->filter_rings) return;
00192 for(std::vector<Ellipse>::iterator a = ellipses_.begin(); a != ellipses_.end(); a++) {
00193 if((a->innerRing >= 0) || (a->outerRing >= 0) || (a->detection != VALID)) continue;
00194 double threshold_center = a->radiusEllipseMax * param_->threshold_ring_center;
00195 for(std::vector<Ellipse>::iterator b = ellipses_.begin(); b != ellipses_.end(); b++) {
00196 if((a->id == b->id) || (b->innerRing != -1) || (b->outerRing != -1) || (b->detection != VALID) ) {
00197 continue;
00198 }
00199 double d = cv::norm(a->boxEllipse.center - b->boxEllipse.center);
00200 if(d < threshold_center) {
00201 Ellipse *outer = &(*a), *inner = &(*b);
00202 if(a->radiusEllipseMax < b->radiusEllipseMax) outer = &(*b), inner = &(*a);
00203 double ratioRadiusRingMax = fabs(inner->radiusEllipseMax / outer->radiusEllipseMax-0.5);
00204 double ratioRadiusRingMin = fabs(inner->radiusEllipseMax / outer->radiusEllipseMax-0.5);
00205 if((ratioRadiusRingMax > param_->threshold_ring_ratio) || (ratioRadiusRingMin > param_->threshold_ring_ratio)) {
00206 continue;
00207 }
00208 outer->innerRing = inner->id;
00209 inner->outerRing = outer->id;
00210 inner->detection = INVALID_IS_INNER_RING;
00211 break;
00212 }
00213 }
00214 if((a->innerRing == -1) && (a->outerRing == -1)) a->detection = INVALID_NO_RING;
00215 }
00216 }
00217
00218 void EllipsesDetection::next() {
00219 contours_.clear();
00220 ellipses_.clear();
00221 tstampLast_ = tstamp_;
00222 }
00223
00224 EllipsesDetection::DetectionState EllipsesDetection::filterContourMean(Ellipse &ellipse) {
00225 if(!param_->filter_contour_mean || (ellipse.detection != VALID)) return ellipse.detection;
00226 const std::vector<cv::Point2f> &contour = *(ellipse.contourUndistort.get());
00227 ellipse.distances = boost::shared_ptr<std::vector<double> >(new std::vector<double> );
00228 std::vector<double > &distances = *(ellipse.distances.get());
00229 const cv::Point2f &pc = ellipse.boxEllipse.center;
00230 double angle = M_PI/180.0 * (double) ellipse.boxEllipse.angle;
00231 double ca = cos(angle), sa = sin(angle);
00232 double a = ellipse.boxEllipse.size.width/2., b = ellipse.boxEllipse.size.height/2.;
00233 double sum = 0;
00234 distances.reserve(contour.size());
00235 for(unsigned int i = 0; i < contour.size(); i++) {
00236 double dx = contour[i].x - pc.x, dy = contour[i].y - pc.y;
00237 double u = ca*dx + sa*dy, v = -sa*dx + ca*dy;
00238 cv::Point2d p(contour[i].x - pc.x, contour[i].y - pc.y);
00239 double d = (u*u)/(a*a) + (v*v)/(b*b);
00240 distances.push_back(d);
00241 sum += d;
00242
00243 }
00244 double mean = sum / distances.size();
00245 double diff = fabs((mean - 1.));
00246 if(diff > param_->threshold_contour_mean) {
00247 ellipse.detection = INVALID_CONTOUR_MEAN;
00248 }
00249 return ellipse.detection;
00250 }
00251
00252
00253 void EllipsesDetection::estimatePoses() {
00254 if(param_->pose_estimation == POSE_ESTIMATION_OFF) return;
00255 cv::Point2f pi[4];
00256 if(param_->circle_diameter <= 0) return;
00257 cv::Mat_<double> rvec, tvec;
00258 double radius = param_->circle_diameter / 2.0;
00259 cv::Mat objectPoints = (cv::Mat_<double>(5,3) << 0, 0, 0, -radius, +radius, 0, +radius, +radius, 0, +radius, -radius, 0, -radius, -radius, 0);
00260 for(std::vector<Ellipse>::iterator it = ellipses_.begin(); it != ellipses_.end(); it++) {
00261 Ellipse &ellipse = *it;
00262 if(ellipse.detection != VALID) continue;
00263
00264 ellipse.boxEllipse.points(pi);
00265 cv::Point2f& pc = ellipse.boxEllipse.center;
00266 cv::Mat imagePoints = (cv::Mat_<double>(5,2) << pc.x, pc.y, pi[0].x, pi[0].y, pi[1].x, pi[1].y, pi[2].x, pi[2].y, pi[3].x, pi[3].y);
00267 switch(param_->pose_estimation) {
00268 case POSE_ESTIMATION_SOLVEPNP:
00269 cv::solvePnP(objectPoints, imagePoints, camera_.cameraMatrix, camera_.distCoeffs, rvec, tvec);
00270 cv::Rodrigues(rvec, ellipse.cone.R[0]);
00271 ellipse.cone.translations[0].x = tvec(0), ellipse.cone.translations[0].y = tvec(1), ellipse.cone.translations[0].z = tvec(2);
00272 ellipse.cone.rotation2Normal(0);
00273 ellipse.cone.R[1] = ellipse.cone.R[0].clone();
00274 ellipse.cone.rotation2Normal(1);
00275 break;
00276 case POSE_ESTIMATION_FROM_ELLIPSE:
00277 ellipse.cone.set(ellipse.boxEllipse, camera_.projectionMatrix);
00278 ellipse.cone.pose(camera_.projectionMatrix, camera_.distCoeffs, param_->circle_diameter/2.);
00279 ellipse.cone.normal2Roation(0);
00280 ellipse.cone.normal2Roation(1);
00281 break;
00282 default:
00283 continue;
00284 }
00285 }
00286 markers_.clear();
00287 for(std::vector<Ellipse>::iterator ellipse = ellipses_.begin(); ellipse != ellipses_.end(); ellipse++) {
00288 if(ellipse->detection != VALID) continue;
00289 markers_.push_back(ellipse->cone);
00290 markers_.back().id = markers_.size()-1;
00291 markers_.back().tstamp = tstamp_;
00292 }
00293
00294 }
00295
00296
00297 void EllipsesDetection::ObliqueCone::rotation2Normal(int i) {
00298 cv::Mat_<double> tvec(translations[i]);
00299 cv::Mat_<double> nvec = R[i] * (cv::Mat_<double>(3,1) << 0, 0, 1);
00300 double d0 = cv::norm(tvec - nvec);
00301 double d1 = cv::norm(tvec + nvec);
00302 if(d1 < d0) {
00303 nvec = -nvec;
00304 }
00305 normals[i][0] = nvec(0), normals[i][1] = nvec(1), normals[i][2] = nvec(2);
00306 }
00307 void EllipsesDetection::ObliqueCone::normal2Roation(int i) {
00308 cv::Mat_<double> unitZ = (cv::Mat_<double>(3,1) << 0, 0, 1);
00309 cv::Mat_<double> nvec(normals[i]);
00310 nvec = nvec/cv::norm(nvec);
00311 cv::Mat_<double> c2 = nvec;
00312 cv::Mat_<double> c1 = unitZ.cross(c2);
00313 cv::Mat_<double> c0 = c1.cross(c2);
00314 c1 = c1/cv::norm(c1);
00315 c0 = c0/cv::norm(c0);
00316 R[i] = (cv::Mat_<double>(3,3) << c0(0), c1(0), c2(0), c0(1), c1(1), c2(1), c0(2), c1(2), c2(2));
00317 }
00318
00319
00320 double EllipsesDetection::ObliqueCone::distance(const cv::Point2d p) {
00321 cv::Mat_<double> P = (cv::Mat_<double>(3,1) << p.x, p.y, 1);
00322 cv::Mat_<double> D = P.t() * C * P;
00323 double d = D(0,0);
00324 return d;
00325 }
00326 void EllipsesDetection::ObliqueCone::set(cv::RotatedRect box, cv::Mat_<double> intrinsic) {
00327 double a = box.size.width/2., b = box.size.height/2.;
00328 double angle = M_PI/180.0 * (float) box.angle;
00329 double ca = cos(angle), sa = sin(angle);
00330 double cx = intrinsic(0,2), cy = intrinsic(1,2);
00331 cv::Mat_<double> Re = (cv::Mat_<double>(2,2) << ca, -sa, sa, ca);
00332 cv::Mat_<double> ABInvTAB = (cv::Mat_<double>(2,2) << 1./(a*a), 0., 0., 1./(b*b));
00333 cv::Mat_<double> X0 = (cv::Mat_<double>(2,1) << box.center.x-cx, box.center.y-cy);
00334 cv::Mat_<double> M = Re * ABInvTAB * Re.t();
00335 cv::Mat_<double> Mf = X0.t() * M * X0;
00336 double A = M(0,0);
00337 double B = M(0,1);
00338 double C = M(1,1);
00339 double D = - A * X0(0) - B * X0(1);
00340 double E = - B * X0(0) - C * X0(1);
00341 double F = Mf(0,0) - 1.0;
00342 this->C = (cv::Mat_<double>(3,3) << A, B, D,
00343 B, C, E,
00344 D, E, F);
00345 }
00346
00347
00348
00349
00350 void EllipsesDetection::ObliqueCone::pose(cv::Mat_<double> intrinsic, cv::Mat_<double> distCoeffs, double radius) {
00351 cv::Mat_<double> Q, V, E;
00352
00353 double fx = intrinsic(0,0), fy = intrinsic(1,1);
00354 double focalLength = (fx+fy)/2.0;
00355 if(focalLength == 0) return;
00356 Q = this->C.clone();
00357 Q(0,0) = this->C(0,0);
00358 Q(0,1) = this->C(0,1);
00359 Q(0,2) = this->C(0,2) / (focalLength);
00360 Q(1,0) = this->C(1,0);
00361 Q(1,1) = this->C(1,1);
00362 Q(1,2) = this->C(1,2) / (focalLength);
00363 Q(2,0) = this->C(2,0) / (focalLength);
00364 Q(2,1) = this->C(2,1) / (focalLength);
00365 Q(2,2) = this->C(2,2) / (focalLength*focalLength);
00366
00367 cv::eigen(Q, E, V);
00368 V = V.t();
00369 double e1 = E.at<double>(0);
00370 double e2 = E.at<double>(1);
00371 double e3 = E.at<double>(2);
00372 double S1[] = {+1,+1,+1,+1,-1,-1,-1,-1};
00373 double S2[] = {+1,+1,-1,-1,+1,+1,-1,-1};
00374 double S3[] = {+1,-1,+1,-1,+1,-1,+1,-1};
00375
00376 double g = sqrt((e2-e3)/(e1-e3));
00377 double h = sqrt((e1-e2)/(e1-e3));
00378 translations[0] = translations[1] = cv::Point3d(0,0,0);
00379 normals[0] = normals[1] = cv::Vec3d(0,0,0);
00380 projections[0] = projections[1] = cv::Point2d(0,0);
00381 unsigned int k = 0;
00382 for(int i = 0; i < 8; i++) {
00383
00384 double z0 = S3[i] * (e2 * radius) / sqrt(-e1*e3);
00385 double Tx = S2[i] * e3/e2 * h;
00386 double Ty = 0.;
00387 double Tz = -S1[i] * e1/e2 * g;
00388 double Nx = S2[i] * h;
00389 double Ny = 0.;
00390 double Nz = -S1[i] * g;
00391
00392 cv::Mat_<double> t = (z0 * V * (cv::Mat_<double>(3,1) << Tx, Ty, Tz));
00393 cv::Mat_<double> n = (V * (cv::Mat_<double>(3,1) << Nx, Ny, Nz));
00394
00395
00396 if((t(2) > 0) && (n(2)<0)) {
00397 if(k > 1) continue;
00398 translations[k] = cv::Point3d(t(0), t(1), t(2));
00399 normals[k] = cv::Vec3d(n(0), n(1), n(2));
00400
00401 cv::Mat_<double> Pc = intrinsic * t;
00402 projections[k].x = Pc(0)/Pc(2);
00403 projections[k].y = Pc(1)/Pc(2);
00404 k++;
00405 }
00406 }
00407 }
00408