void camera_calib_guiDialog::show3Dview() { mrpt::opengl::COpenGLScenePtr scene = mrpt::opengl::COpenGLScene::Create(); const unsigned int check_size_x = edSizeX->GetValue(); const unsigned int check_size_y = edSizeY->GetValue(); const double check_squares_length_X_meters = 0.001 * atof( string(edLengthX->GetValue().mb_str()).c_str() ); const double check_squares_length_Y_meters = 0.001 * atof( string(edLengthY->GetValue().mb_str()).c_str() ); if (!check_squares_length_X_meters || !check_squares_length_Y_meters) return; opengl::CGridPlaneXYPtr grid = opengl::CGridPlaneXY::Create(0,check_size_x*check_squares_length_X_meters, 0, check_size_y*check_squares_length_Y_meters, 0, check_squares_length_X_meters ); scene->insert( grid ); for (TCalibrationImageList::iterator it=lst_images.begin();it!=lst_images.end();++it) { if (!it->second.detected_corners.empty()) { mrpt::opengl::CSetOfObjectsPtr cor = mrpt::opengl::stock_objects::CornerXYZ(); cor->setName( mrpt::system::extractFileName(it->first) ); cor->enableShowName(true); cor->setScale(0.1); cor->setPose( it->second.reconstructed_camera_pose ); scene->insert( cor ); } } //scene->insert( mrpt::opengl::stock_objects::CornerXYZ() ); this->m_3Dview->m_openGLScene = scene; this->m_3Dview->Refresh(); }
// Update the listbox from lst_img_files void camera_calib_guiDialog::updateListOfImages() { lbFiles->Clear(); for (TCalibrationImageList::iterator s=lst_images.begin();s!=lst_images.end();++s) lbFiles->Append(_U(s->first.c_str())); btnSaveImages->Enable( !lst_images.empty() ); refreshDisplayedImage(); }
void camera_calib_guiDialog::OnbtnSaveImagesClick(wxCommandEvent& event) { try { if (lst_images.empty()) return; wxDirDialog dlg(this,_("Select the directory where to save the images"),_(".")); if (dlg.ShowModal()==wxID_OK) { string dir = string(dlg.GetPath().mb_str()); for (TCalibrationImageList::iterator s=lst_images.begin();s!=lst_images.end();++s) s->second.img_original.saveToFile( dir+string("/")+s->first+string(".png") ); } } catch(std::exception &e) { wxMessageBox(_U(e.what()),_("Error"),wxICON_INFORMATION,this); } }
/* ------------------------------------------------------- checkerBoardCameraCalibration ------------------------------------------------------- */ bool mrpt::vision::checkerBoardCameraCalibration( TCalibrationImageList &images, unsigned int check_size_x, unsigned int check_size_y, double check_squares_length_X_meters, double check_squares_length_Y_meters, mrpt::utils::TCamera &out_camera_params, bool normalize_image, double *out_MSE, bool skipDrawDetectedImgs, bool useScaramuzzaAlternativeDetector ) { #if MRPT_HAS_OPENCV try { ASSERT_(check_size_x>2) ASSERT_(check_size_y>2) ASSERT_(check_squares_length_X_meters>0) ASSERT_(check_squares_length_Y_meters>0) if (images.size()<1) { std::cout << "ERROR: No input images." << std::endl; return false; } const unsigned CORNERS_COUNT = check_size_x * check_size_y; const CvSize check_size = cvSize(check_size_x, check_size_y); // First: Assure all images are loaded: // ------------------------------------------- TCalibrationImageList::iterator it; for (it=images.begin();it!=images.end();it++) { TImageCalibData &dat = it->second; dat.projectedPoints_distorted.clear(); // Clear reprojected points. dat.projectedPoints_undistorted.clear(); // Skip if images are marked as "externalStorage": if (!dat.img_original.isExternallyStored() && !mrpt::system::extractFileExtension(it->first).empty() ) { if (!dat.img_original.loadFromFile(it->first)) THROW_EXCEPTION_CUSTOM_MSG1("Error reading image: %s",it->first.c_str()); dat.img_checkboard = dat.img_original; dat.img_rectified = dat.img_original; } } // For each image, find checkerboard corners: // ----------------------------------------------- //const unsigned int N = images.size(); unsigned int i; vector<CvPoint2D64f> corners_list; // = new CvPoint2D32f[ N * CORNERS_COUNT]; unsigned int valid_detected_imgs = 0; CvSize imgSize = cvSize(0,0); vector<string> pointsIdx2imageFile; int find_chess_flags = CV_CALIB_CB_ADAPTIVE_THRESH; if (normalize_image) find_chess_flags |= CV_CALIB_CB_NORMALIZE_IMAGE; for (i=0,it=images.begin();it!=images.end();it++,i++) { TImageCalibData &dat = it->second; // Make grayscale version: const CImage img_gray( dat.img_original, FAST_REF_OR_CONVERT_TO_GRAY ); if (!i) { imgSize = cvSize(img_gray.getWidth(),img_gray.getHeight() ); out_camera_params.ncols = imgSize.width; out_camera_params.nrows = imgSize.height; } else { if (imgSize.height != (int)img_gray.getHeight() || imgSize.width != (int)img_gray.getWidth()) { std::cout << "ERROR: All the images must have the same size" << std::endl; return false; } } // Try with expanded versions of the image if it fails to detect the checkerboard: unsigned corners_count; bool corners_found=false; corners_count = CORNERS_COUNT; corners_list.resize( (1+valid_detected_imgs)*CORNERS_COUNT ); dat.detected_corners.clear(); // Do detection (this includes the "refine corners" with cvFindCornerSubPix): vector<TPixelCoordf> detectedCoords; corners_found = mrpt::vision::findChessboardCorners( img_gray, detectedCoords, check_size_x,check_size_y, normalize_image, // normalize_image useScaramuzzaAlternativeDetector ); corners_count = detectedCoords.size(); // Copy the data into the overall array of coords: ASSERT_(detectedCoords.size()<=CORNERS_COUNT); for (size_t p=0;p<detectedCoords.size();p++) { corners_list[valid_detected_imgs*CORNERS_COUNT+p].x = detectedCoords[p].x; corners_list[valid_detected_imgs*CORNERS_COUNT+p].y = detectedCoords[p].y; } if (corners_found && corners_count!=CORNERS_COUNT) corners_found = false; cout << format("Img %s: %s\n", mrpt::system::extractFileName(it->first).c_str() , corners_found ? "DETECTED" : "NOT DETECTED" ); if( corners_found ) { // save the corners in the data structure: int x, y; unsigned int k; for( y = 0, k = 0; y < check_size.height; y++ ) for( x = 0; x < check_size.width; x++, k++ ) dat.detected_corners.push_back( mrpt::utils::TPixelCoordf( corners_list[valid_detected_imgs*CORNERS_COUNT + k].x, corners_list[valid_detected_imgs*CORNERS_COUNT + k].y ) ); // Draw the checkerboard in the corresponding image: // ---------------------------------------------------- if ( !dat.img_original.isExternallyStored() ) { const int r = 4; CvPoint prev_pt= cvPoint(0, 0); const int line_max = 8; CvScalar line_colors[8]; line_colors[0] = CV_RGB(255,0,0); line_colors[1] = CV_RGB(255,128,0); line_colors[2] = CV_RGB(255,128,0); line_colors[3] = CV_RGB(200,200,0); line_colors[4] = CV_RGB(0,255,0); line_colors[5] = CV_RGB(0,200,200); line_colors[6] = CV_RGB(0,0,255); line_colors[7] = CV_RGB(255,0,255); // Checkboad as color image: dat.img_original.colorImage( dat.img_checkboard ); void *rgb_img = dat.img_checkboard.getAs<IplImage>(); for( y = 0, k = 0; y < check_size.height; y++ ) { CvScalar color = line_colors[y % line_max]; for( x = 0; x < check_size.width; x++, k++ ) { CvPoint pt; pt.x = cvRound(corners_list[valid_detected_imgs*CORNERS_COUNT + k].x); pt.y = cvRound(corners_list[valid_detected_imgs*CORNERS_COUNT + k].y); if( k != 0 ) cvLine( rgb_img, prev_pt, pt, color ); cvLine( rgb_img, cvPoint( pt.x - r, pt.y - r ), cvPoint( pt.x + r, pt.y + r ), color ); cvLine( rgb_img, cvPoint( pt.x - r, pt.y + r), cvPoint( pt.x + r, pt.y - r), color ); cvCircle( rgb_img, pt, r+1, color ); prev_pt = pt; } } } } if( corners_found ) { pointsIdx2imageFile.push_back( it->first ); valid_detected_imgs++; } } // end find corners std::cout << valid_detected_imgs << " valid images." << std::endl; if (!valid_detected_imgs) { std::cout << "ERROR: No valid images. Perhaps the checkerboard size is incorrect?" << std::endl; return false; } // --------------------------------------------- // Calculate the camera parameters // --------------------------------------------- // Was: FillEtalonObjPoints vector<CvPoint3D64f> obj_points( valid_detected_imgs * CORNERS_COUNT ); { unsigned int y,k; for( y = 0, k = 0; y < check_size_y; y++ ) { for( unsigned int x = 0; x < check_size_x; x++, k++ ) { obj_points[k].x =-check_squares_length_X_meters * x; // The "-" is for convenience, so the camera poses appear with Z>0 obj_points[k].y = check_squares_length_Y_meters * y; obj_points[k].z = 0; } } } // Repeat the pattern N times: for( i= 1; i< valid_detected_imgs; i++ ) memcpy( &obj_points[CORNERS_COUNT*i], &obj_points[0], CORNERS_COUNT*sizeof(obj_points[0])); // Number of detected points in each image (constant): vector<int> numsPoints(valid_detected_imgs, (int)CORNERS_COUNT ); double proj_matrix[9]; double distortion[4]; vector<CvPoint3D64f> transVects( valid_detected_imgs ); vector<double> rotMatrs( valid_detected_imgs * 9 ); // Calibrate camera cvCalibrateCamera_64d( valid_detected_imgs, &numsPoints[0], imgSize, &corners_list[0], &obj_points[0], distortion, proj_matrix, (double*)&transVects[0], &rotMatrs[0], 0 ); // Load matrix: out_camera_params.intrinsicParams = CMatrixDouble33( proj_matrix ); out_camera_params.dist.assign(0); for (int i=0;i<4;i++) out_camera_params.dist[i] = distortion[i]; // Load camera poses: for (i=0;i<valid_detected_imgs;i++) { const double *R = &rotMatrs[9*i]; CMatrixDouble HM(4,4); HM.zeros(); HM(3,3)=1; HM(0,0)=R[0]; HM(1,0)=R[3]; HM(2,0)=R[6]; HM(0,1)=R[1]; HM(1,1)=R[4]; HM(2,1)=R[7]; HM(0,2)=R[2]; HM(1,2)=R[5]; HM(2,2)=R[8]; HM(0,3)=transVects[i].x; HM(1,3)=transVects[i].y; HM(2,3)=transVects[i].z; CPose3D p = CPose3D(0,0,0) - CPose3D(HM); images[ pointsIdx2imageFile[i] ].reconstructed_camera_pose = p; std::cout << "Img: " << mrpt::system::extractFileName(pointsIdx2imageFile[i]) << ": " << p << std::endl; } { CConfigFileMemory cfg; out_camera_params.saveToConfigFile("CAMERA_PARAMS",cfg); std::cout << cfg.getContent() << std::endl; } // ---------------------------------------- // Undistort images: // ---------------------------------------- for (it=images.begin();it!=images.end();it++) { TImageCalibData &dat = it->second; if (!dat.img_original.isExternallyStored()) dat.img_original.rectifyImage( dat.img_rectified, out_camera_params); } // end undistort // ----------------------------------------------- // Reproject points to measure the fit sqr error // ----------------------------------------------- double sqrErr = 0; for (i=0;i<valid_detected_imgs;i++) { TImageCalibData & dat = images[ pointsIdx2imageFile[i] ]; if (dat.detected_corners.size()!=CORNERS_COUNT) continue; // Reproject all the points into pixel coordinates: // ----------------------------------------------------- vector<TPoint3D> lstPatternPoints(CORNERS_COUNT); // Points as seen from the camera: for (unsigned int p=0;p<CORNERS_COUNT;p++) lstPatternPoints[p] = TPoint3D(obj_points[p].x,obj_points[p].y,obj_points[p].z); vector<TPixelCoordf> &projectedPoints = dat.projectedPoints_undistorted; vector<TPixelCoordf> &projectedPoints_distorted = dat.projectedPoints_distorted; vision::pinhole::projectPoints_no_distortion( lstPatternPoints, // Input points dat.reconstructed_camera_pose, out_camera_params.intrinsicParams, // calib matrix projectedPoints // Output points in pixels ); vision::pinhole::projectPoints_with_distortion( lstPatternPoints, // Input points dat.reconstructed_camera_pose, out_camera_params.intrinsicParams, // calib matrix out_camera_params.getDistortionParamsAsVector(), projectedPoints_distorted// Output points in pixels ); ASSERT_(projectedPoints.size()==CORNERS_COUNT); ASSERT_(projectedPoints_distorted.size()==CORNERS_COUNT); for (unsigned int p=0;p<CORNERS_COUNT;p++) { const double px = projectedPoints[p].x; const double py = projectedPoints[p].y; const double px_d = projectedPoints_distorted[p].x; const double py_d = projectedPoints_distorted[p].y; // Only draw if the img is NOT external: if (!dat.img_original.isExternallyStored()) { if( px >= 0 && px < imgSize.width && py >= 0 && py < imgSize.height ) cvCircle( dat.img_rectified.getAs<IplImage>(), cvPoint(px,py), 4, CV_RGB(0,0,255) ); } // Accumulate error: sqrErr+=square(px_d-dat.detected_corners[p].x)+square(py_d-dat.detected_corners[p].y); // Error relative to the original (distorted) image. } } if (valid_detected_imgs) { sqrErr /= CORNERS_COUNT*valid_detected_imgs; std::cout << "Average err. of reprojection: " << sqrt(sqrErr) << " pixels" << std::endl; } if(out_MSE) *out_MSE = sqrt(sqrErr); return true; } catch(std::exception &e) { std::cout << e.what() << std::endl; return false; } #else THROW_EXCEPTION("Function not available: MRPT was compiled without OpenCV") #endif }
/* ------------------------------------------------------- checkerBoardCameraCalibration ------------------------------------------------------- */ bool mrpt::vision::checkerBoardCameraCalibration( TCalibrationImageList &images, unsigned int check_size_x, unsigned int check_size_y, double check_squares_length_X_meters, double check_squares_length_Y_meters, mrpt::utils::TCamera &out_camera_params, bool normalize_image, double *out_MSE, bool skipDrawDetectedImgs, bool useScaramuzzaAlternativeDetector ) { MRPT_UNUSED_PARAM(skipDrawDetectedImgs); #if MRPT_HAS_OPENCV try { ASSERT_(check_size_x>2) ASSERT_(check_size_y>2) ASSERT_(check_squares_length_X_meters>0) ASSERT_(check_squares_length_Y_meters>0) if (images.size()<1) { std::cout << "ERROR: No input images." << std::endl; return false; } const unsigned CORNERS_COUNT = check_size_x * check_size_y; const CvSize check_size = cvSize(check_size_x, check_size_y); // Fill the pattern of expected pattern points only once out of the loop: vector<cv::Point3f> pattern_obj_points(CORNERS_COUNT); { unsigned int y,k; for( y = 0, k = 0; y < check_size_y; y++ ) { for( unsigned int x = 0; x < check_size_x; x++, k++ ) { pattern_obj_points[k].x =-check_squares_length_X_meters * x; // The "-" is for convenience, so the camera poses appear with Z>0 pattern_obj_points[k].y = check_squares_length_Y_meters * y; pattern_obj_points[k].z = 0; } } } // First: Assure all images are loaded: // ------------------------------------------- TCalibrationImageList::iterator it; for (it=images.begin();it!=images.end();++it) { TImageCalibData &dat = it->second; dat.projectedPoints_distorted.clear(); // Clear reprojected points. dat.projectedPoints_undistorted.clear(); // Skip if images are marked as "externalStorage": if (!dat.img_original.isExternallyStored() && !mrpt::system::extractFileExtension(it->first).empty() ) { if (!dat.img_original.loadFromFile(it->first)) THROW_EXCEPTION_CUSTOM_MSG1("Error reading image: %s",it->first.c_str()); dat.img_checkboard = dat.img_original; dat.img_rectified = dat.img_original; } } // For each image, find checkerboard corners: // ----------------------------------------------- vector<vector<cv::Point3f> > objectPoints; // final container for detected stuff vector<vector<cv::Point2f> > imagePoints; // final container for detected stuff unsigned int valid_detected_imgs = 0; vector<string> pointsIdx2imageFile; cv::Size imgSize(0,0); unsigned int i; for (i=0,it=images.begin();it!=images.end();it++,i++) { TImageCalibData &dat = it->second; // Make grayscale version: const CImage img_gray( dat.img_original, FAST_REF_OR_CONVERT_TO_GRAY ); if (!i) { imgSize = cv::Size(img_gray.getWidth(),img_gray.getHeight() ); out_camera_params.ncols = imgSize.width; out_camera_params.nrows = imgSize.height; } else { if (imgSize.height != (int)img_gray.getHeight() || imgSize.width != (int)img_gray.getWidth()) { std::cout << "ERROR: All the images must have the same size" << std::endl; return false; } } // Try with expanded versions of the image if it fails to detect the checkerboard: unsigned corners_count; bool corners_found=false; corners_count = CORNERS_COUNT; vector<cv::Point2f> this_img_pts(CORNERS_COUNT); // Temporary buffer for points, to be added if the points pass the checks. dat.detected_corners.clear(); // Do detection (this includes the "refine corners" with cvFindCornerSubPix): vector<TPixelCoordf> detectedCoords; corners_found = mrpt::vision::findChessboardCorners( img_gray, detectedCoords, check_size_x,check_size_y, normalize_image, // normalize_image useScaramuzzaAlternativeDetector ); corners_count = detectedCoords.size(); // Copy the data into the overall array of coords: ASSERT_(detectedCoords.size()<=CORNERS_COUNT); for (size_t p=0;p<detectedCoords.size();p++) { this_img_pts[p].x = detectedCoords[p].x; this_img_pts[p].y = detectedCoords[p].y; } if (corners_found && corners_count!=CORNERS_COUNT) corners_found = false; cout << format("Img %s: %s\n", mrpt::system::extractFileName(it->first).c_str() , corners_found ? "DETECTED" : "NOT DETECTED" ); if( corners_found ) { // save the corners in the data structure: int x, y; unsigned int k; for( y = 0, k = 0; y < check_size.height; y++ ) for( x = 0; x < check_size.width; x++, k++ ) dat.detected_corners.push_back( mrpt::utils::TPixelCoordf( this_img_pts[k].x, this_img_pts[k].y ) ); // Draw the checkerboard in the corresponding image: // ---------------------------------------------------- if ( !dat.img_original.isExternallyStored() ) { const int r = 4; CvPoint prev_pt= cvPoint(0, 0); const int line_max = 8; CvScalar line_colors[8]; line_colors[0] = CV_RGB(255,0,0); line_colors[1] = CV_RGB(255,128,0); line_colors[2] = CV_RGB(255,128,0); line_colors[3] = CV_RGB(200,200,0); line_colors[4] = CV_RGB(0,255,0); line_colors[5] = CV_RGB(0,200,200); line_colors[6] = CV_RGB(0,0,255); line_colors[7] = CV_RGB(255,0,255); // Checkboad as color image: dat.img_original.colorImage( dat.img_checkboard ); void *rgb_img = dat.img_checkboard.getAs<IplImage>(); for( y = 0, k = 0; y < check_size.height; y++ ) { CvScalar color = line_colors[y % line_max]; for( x = 0; x < check_size.width; x++, k++ ) { CvPoint pt; pt.x = cvRound(this_img_pts[k].x); pt.y = cvRound(this_img_pts[k].y); if( k != 0 ) cvLine( rgb_img, prev_pt, pt, color ); cvLine( rgb_img, cvPoint( pt.x - r, pt.y - r ), cvPoint( pt.x + r, pt.y + r ), color ); cvLine( rgb_img, cvPoint( pt.x - r, pt.y + r), cvPoint( pt.x + r, pt.y - r), color ); cvCircle( rgb_img, pt, r+1, color ); prev_pt = pt; } } } // Accept this image as good: pointsIdx2imageFile.push_back( it->first ); imagePoints.push_back( this_img_pts ); objectPoints.push_back( pattern_obj_points ); valid_detected_imgs++; } } // end find corners std::cout << valid_detected_imgs << " valid images." << std::endl; if (!valid_detected_imgs) { std::cout << "ERROR: No valid images. Perhaps the checkerboard size is incorrect?" << std::endl; return false; } // --------------------------------------------- // Calculate the camera parameters // --------------------------------------------- // Calibrate camera cv::Mat cameraMatrix, distCoeffs(1,5,CV_64F,cv::Scalar::all(0)); vector<cv::Mat> rvecs, tvecs; const double cv_calib_err = cv::calibrateCamera( objectPoints,imagePoints,imgSize, cameraMatrix, distCoeffs, rvecs, tvecs, 0 /*flags*/ ); // Load matrix: out_camera_params.intrinsicParams = CMatrixDouble33( cameraMatrix.ptr<double>() ); out_camera_params.dist.assign(0); for (int i=0;i<5;i++) out_camera_params.dist[i] = distCoeffs.ptr<double>()[i]; // Load camera poses: for (i=0;i<valid_detected_imgs;i++) { CMatrixDouble44 HM; HM.zeros(); HM(3,3)=1; { // Convert rotation vectors -> rot matrices: cv::Mat cv_rot; cv::Rodrigues(rvecs[i],cv_rot); Eigen::Matrix3d rot; cv::my_cv2eigen(cv_rot, rot ); HM.block<3,3>(0,0) = rot; } { Eigen::Matrix<double,3,1> trans; cv::my_cv2eigen(tvecs[i], trans ); HM.block<3,1>(0,3) = trans; } CPose3D p = CPose3D(0,0,0) - CPose3D(HM); images[ pointsIdx2imageFile[i] ].reconstructed_camera_pose = p; std::cout << "Img: " << mrpt::system::extractFileName(pointsIdx2imageFile[i]) << ": " << p << std::endl; } { CConfigFileMemory cfg; out_camera_params.saveToConfigFile("CAMERA_PARAMS",cfg); std::cout << cfg.getContent() << std::endl; } // ---------------------------------------- // Undistort images: // ---------------------------------------- for (it=images.begin();it!=images.end();++it) { TImageCalibData &dat = it->second; if (!dat.img_original.isExternallyStored()) dat.img_original.rectifyImage( dat.img_rectified, out_camera_params); } // end undistort // ----------------------------------------------- // Reproject points to measure the fit sqr error // ----------------------------------------------- double sqrErr = 0; for (i=0;i<valid_detected_imgs;i++) { TImageCalibData & dat = images[ pointsIdx2imageFile[i] ]; if (dat.detected_corners.size()!=CORNERS_COUNT) continue; // Reproject all the points into pixel coordinates: // ----------------------------------------------------- vector<TPoint3D> lstPatternPoints(CORNERS_COUNT); // Points as seen from the camera: for (unsigned int p=0;p<CORNERS_COUNT;p++) lstPatternPoints[p] = TPoint3D(pattern_obj_points[p].x,pattern_obj_points[p].y,pattern_obj_points[p].z); vector<TPixelCoordf> &projectedPoints = dat.projectedPoints_undistorted; vector<TPixelCoordf> &projectedPoints_distorted = dat.projectedPoints_distorted; vision::pinhole::projectPoints_no_distortion( lstPatternPoints, // Input points dat.reconstructed_camera_pose, out_camera_params.intrinsicParams, // calib matrix projectedPoints // Output points in pixels ); vision::pinhole::projectPoints_with_distortion( lstPatternPoints, // Input points dat.reconstructed_camera_pose, out_camera_params.intrinsicParams, // calib matrix out_camera_params.getDistortionParamsAsVector(), projectedPoints_distorted// Output points in pixels ); ASSERT_(projectedPoints.size()==CORNERS_COUNT); ASSERT_(projectedPoints_distorted.size()==CORNERS_COUNT); for (unsigned int p=0;p<CORNERS_COUNT;p++) { const double px = projectedPoints[p].x; const double py = projectedPoints[p].y; const double px_d = projectedPoints_distorted[p].x; const double py_d = projectedPoints_distorted[p].y; // Only draw if the img is NOT external: if (!dat.img_original.isExternallyStored()) { if( px >= 0 && px < imgSize.width && py >= 0 && py < imgSize.height ) cvCircle( dat.img_rectified.getAs<IplImage>(), cvPoint(px,py), 4, CV_RGB(0,0,255) ); } // Accumulate error: sqrErr+=square(px_d-dat.detected_corners[p].x)+square(py_d-dat.detected_corners[p].y); // Error relative to the original (distorted) image. } } if (valid_detected_imgs) { sqrErr /= CORNERS_COUNT*valid_detected_imgs; std::cout << "Average err. of reprojection: " << sqrt(sqrErr) << " pixels (OpenCV error=" << cv_calib_err << ")\n"; } if(out_MSE) *out_MSE = sqrt(sqrErr); return true; } catch(std::exception &e) { std::cout << e.what() << std::endl; return false; } #else THROW_EXCEPTION("Function not available: MRPT was compiled without OpenCV") #endif }