int main(int argc, char** argv) { try { if (readArguments(argc, argv) == false) return 0; // read board configuration TheBoardConfig.readFromFile(TheBoardConfigFile); // Open video input source if (TheInputVideo == "") // read from camera TheVideoCapturer.open(0); else TheVideoCapturer.open(TheInputVideo); if (!TheVideoCapturer.isOpened()) { cerr << "Could not open video" << endl; return -1; } // read first image TheVideoCapturer >> TheInputImage; // read camera paramters if passed TheCameraParams.readFromXMLFile(TheIntrinsicFile); TheCameraParams.resize(TheInputImage.size()); TheBoardDetector.getMarkerDetector().setThresholdParams(25, 7); glutInit(&argc, argv); glutInitWindowPosition(0, 0); glutInitWindowSize(TheInputImage.size().width, TheInputImage.size().height); glutInitDisplayMode(GLUT_RGB | GLUT_DEPTH | GLUT_DOUBLE); glutCreateWindow("ArUco"); glutDisplayFunc(vDrawScene); glutIdleFunc(vIdle); glutReshapeFunc(vResize); glutMouseFunc(vMouse); glClearColor(0.0, 0.0, 0.0, 1.0); glClearDepth(1.0); // these two are necesary for the mask effect glEnable(GL_ALPHA_TEST); glAlphaFunc(GL_GREATER, 0.5); TheGlWindowSize = TheInputImage.size(); vResize(TheGlWindowSize.width, TheGlWindowSize.height); glutMainLoop(); } catch (std::exception& ex) { cout << "Exception :" << ex.what() << endl; } }
int main(int argc,char **argv) { try { if (readArguments (argc,argv)==false) return 0; //read board configuration TheBoardConfig.readFromFile(TheBoardConfigFile); //Open video input source if (TheInputVideo=="live") //read from camera TheVideoCapturer.open(0); else TheVideoCapturer.open(TheInputVideo); if (!TheVideoCapturer.isOpened()) { cerr<<"Could not open video"<<endl; return -1; } //read first image TheVideoCapturer>>TheInputImage; //read camera paramters if passed TheCameraParams.readFromXMLFile(TheIntrinsicFile); TheCameraParams.resize( TheInputImage.size()); //init glut information and init glutInit(&argc, argv); glutInitWindowPosition( 0, 0); glutInitWindowSize(TheInputImage.size().width,TheInputImage.size().height); glutInitDisplayMode( GLUT_RGB | GLUT_DEPTH | GLUT_DOUBLE ); glutCreateWindow( "AruCo" ); glutDisplayFunc( vDrawScene ); glutIdleFunc( vIdle ); glutReshapeFunc( vResize ); glutMouseFunc(vMouse); glClearColor( 0.0, 0.0, 0.0, 1.0 ); glClearDepth( 1.0 ); TheGlWindowSize=TheInputImage.size(); vResize(TheGlWindowSize.width,TheGlWindowSize.height); glutMainLoop(); } catch (std::exception &ex) { cout<<"Exception :"<<ex.what()<<endl; } }
int main(int argc,char **argv) { try { if(argc==1) usage(); readArguments (argc,argv); if (TheIntrinsicFile==""){cerr<<"-f option required"<<endl;return -1;} if (TheMarkerSize==-1){cerr<<"-s option required"<<endl;return -1;} //read from camera if (TheInputVideo=="") TheVideoCapturer.open(0); else TheVideoCapturer.open(TheInputVideo); if (!TheVideoCapturer.isOpened()) { cerr<<"Could not open video"<<endl; return -1; } //read first image TheVideoCapturer>>TheInputImage; //read camera paramters if passed if (isIntrinsicFileYAML) TheCameraParams.readFromXMLFile(TheIntrinsicFile); else TheCameraParams.readFromFile(TheIntrinsicFile); TheCameraParams.resize(TheInputImage.size()); glutInit(&argc, argv); glutInitWindowPosition( 0, 0); glutInitWindowSize(TheInputImage.size().width,TheInputImage.size().height); glutInitDisplayMode( GLUT_RGB | GLUT_DEPTH | GLUT_DOUBLE ); glutCreateWindow( "AruCo" ); glutDisplayFunc( vDrawScene ); glutIdleFunc( vIdle ); glutReshapeFunc( vResize ); glutMouseFunc(vMouse); glClearColor( 0.0, 0.0, 0.0, 1.0 ); glClearDepth( 1.0 ); TheGlWindowSize=TheInputImage.size(); vResize(TheGlWindowSize.width,TheGlWindowSize.height); glutMainLoop(); }catch(std::exception &ex) { cout<<"Exception :"<<ex.what()<<endl; } }
/*! * */ int main(int argc,char **argv) { readArguments (argc,argv); //read board configuration boardConfig.readFromFile(bcon->sval[0]); //Open video input source if (inp->count==0 || strcmp(inp->sval[0], "live")==0) { //read from camera vCapturer.open(0); vCapturer.set(CV_CAP_PROP_FRAME_WIDTH, wid->ival[0]); vCapturer.set(CV_CAP_PROP_FRAME_HEIGHT, hei->ival[0]); int val = CV_FOURCC('M', 'P', 'E', 'G'); vCapturer.set(CV_CAP_PROP_FOURCC, val); } else vCapturer.open(inp->sval[0]); if (!vCapturer.isOpened()) { std::cerr<<"Could not open video"<<std::endl; return -1; } //read first image vCapturer>>inImg; //read camera paramters if passed camParams.readFromXMLFile(ints->sval[0]); camParams.resize( inImg.size()); glutInit(&argc, argv); glutInitWindowPosition( 0, 0); glutInitWindowSize(inImg.size().width,inImg.size().height); glutInitDisplayMode( GLUT_RGB | GLUT_DEPTH | GLUT_DOUBLE ); glutCreateWindow( "AruCo" ); glutDisplayFunc( vDrawScene ); glutIdleFunc( vIdle ); glutReshapeFunc( vResize ); glutMouseFunc(vMouse); glClearColor( 0.0, 0.0, 0.0, 1.0 ); glClearDepth( 1.0 ); glSize=inImg.size(); vResize(glSize.width,glSize.height); glutMainLoop(); }
int main(int argc,char **argv) { ros::init(argc, argv, "aruco_test_on_ros2"); ros::NodeHandle nh; ros::NodeHandle pnh("~"); //read camera parameters camParam.readFromXMLFile("/home/mylove/ws/src/vision_uav/ca150.yml"); cout<< "here is the 1st."<<endl; image_transport::ImageTransport it(nh); image_transport::Subscriber imgSub; nh.param("MKsize", MKsize, double(27)); imgSub = it.subscribe("/uav_cam/image", 5, imageCallback); pub = nh.advertise<geometry_msgs::Vector3>("img_pos",200); ros::spin(); return 0; }
int main(int argc, char** argv) { try { CmdLineParser cml(argc, argv); if (argc < 2 || cml["-h"]) { cerr << "Invalid number of arguments" << endl; cerr << "Usage: (in.avi|live[:camera_index(e.g 0 or 1)]) [-c camera_params.yml] [-s marker_size_in_meters] [-d " "dictionary:ARUCO by default] [-h]" << endl; cerr << "\tDictionaries: "; for (auto dict : aruco::Dictionary::getDicTypes()) cerr << dict << " "; cerr << endl; cerr << "\t Instead of these, you can directly indicate the path to a file with your own generated " "dictionary" << endl; return false; } /////////// PARSE ARGUMENTS string TheInputVideo = argv[1]; // read camera parameters if passed if (cml["-c"]) TheCameraParameters.readFromXMLFile(cml("-c")); float TheMarkerSize = std::stof(cml("-s", "-1")); // aruco::Dictionary::DICT_TYPES TheDictionary= Dictionary::getTypeFromString( cml("-d","ARUCO") ); /////////// OPEN VIDEO // read from camera or from file if (TheInputVideo.find("live") != string::npos) { int vIdx = 0; // check if the :idx is here char cad[100]; if (TheInputVideo.find(":") != string::npos) { std::replace(TheInputVideo.begin(), TheInputVideo.end(), ':', ' '); sscanf(TheInputVideo.c_str(), "%s %d", cad, &vIdx); } cout << "Opening camera index " << vIdx << endl; TheVideoCapturer.open(vIdx); waitTime = 10; } else TheVideoCapturer.open(TheInputVideo); // check video is open if (!TheVideoCapturer.isOpened()) throw std::runtime_error("Could not open video"); ///// CONFIGURE DATA // read first image to get the dimensions TheVideoCapturer >> TheInputImage; if (TheCameraParameters.isValid()) TheCameraParameters.resize(TheInputImage.size()); dictionaryString=cml("-d", "ARUCO"); MDetector.setDictionary(dictionaryString,float(iCorrectionRate)/10. ); // sets the dictionary to be employed (ARUCO,APRILTAGS,ARTOOLKIT,etc) MDetector.setThresholdParams(7, 7); MDetector.setThresholdParamRange(2, 0); // gui requirements : the trackbars to change this parameters iThresParam1 = static_cast<int>(MDetector.getParams()._thresParam1); iThresParam2 = static_cast<int>(MDetector.getParams()._thresParam2); cv::namedWindow("in"); cv::createTrackbar("ThresParam1", "in", &iThresParam1, 25, cvTackBarEvents); cv::createTrackbar("ThresParam2", "in", &iThresParam2, 13, cvTackBarEvents); cv::createTrackbar("correction_rate", "in", &iCorrectionRate, 10, cvTackBarEvents); cv::createTrackbar("EnclosedMarkers", "in", &iEnclosedMarkers, 1, cvTackBarEvents); cv::createTrackbar("ShowAllCandidates", "in", &iShowAllCandidates, 1, cvTackBarEvents); // go! char key = 0; int index = 0,indexSave=0; // capture until press ESC or until the end of the video do { TheVideoCapturer.retrieve(TheInputImage); // copy image double tick = (double)getTickCount(); // for checking the speed // Detection of markers in the image passed TheMarkers = MDetector.detect(TheInputImage, TheCameraParameters, TheMarkerSize); // chekc the speed by calculating the mean speed of all iterations AvrgTime.first += ((double)getTickCount() - tick) / getTickFrequency(); AvrgTime.second++; cout << "\rTime detection=" << 1000 * AvrgTime.first / AvrgTime.second << " milliseconds nmarkers=" << TheMarkers.size() << std::endl; // print marker info and draw the markers in image TheInputImage.copyTo(TheInputImageCopy); if (iShowAllCandidates){ auto candidates=MDetector.getCandidates(); for(auto cand:candidates) Marker(cand,-1).draw(TheInputImageCopy, Scalar(255, 0, 255)); } for (unsigned int i = 0; i < TheMarkers.size(); i++) { cout << TheMarkers[i] << endl; TheMarkers[i].draw(TheInputImageCopy, Scalar(0, 0, 255)); } // draw a 3d cube in each marker if there is 3d info if (TheCameraParameters.isValid() && TheMarkerSize > 0) for (unsigned int i = 0; i < TheMarkers.size(); i++) { CvDrawingUtils::draw3dCube(TheInputImageCopy, TheMarkers[i], TheCameraParameters); CvDrawingUtils::draw3dAxis(TheInputImageCopy, TheMarkers[i], TheCameraParameters); } // DONE! Easy, right? // show input with augmented information and the thresholded image cv::imshow("in", resize(TheInputImageCopy, 1280)); cv::imshow("thres", resize(MDetector.getThresholdedImage(), 1280)); key = cv::waitKey(waitTime); // wait for key to be pressed if (key == 's') waitTime = waitTime == 0 ? 10 : 0; if (key == 'w'){//writes current input image string number=std::to_string(indexSave++); while(number.size()!=3)number+="0"; string imname="arucoimage"+number+".png"; cv::imwrite(imname,TheInputImage); cout<<"saved "<<imname<<endl; } index++; // number of images captured } while (key != 27 && (TheVideoCapturer.grab())); } catch (std::exception& ex) { cout << "Exception :" << ex.what() << endl; } }
int main(int argc, char** argv) { try { CmdLineParser cml(argc, argv); if (argc < 3 || cml["-h"]) { cerr << "Invalid number of arguments" << endl; cerr << "Usage: (in.avi|live) marksetconfig.yml [optional_arguments] \n\t[-c camera_intrinsics.yml] " "\n\t[-s marker_size] \n\t[-pcd out_pcd_file_with_camera_poses] \n\t[-poses out_file_with_poses] " "\n\t[-corner <corner_refinement_method> (0: LINES(default),1 SUBPIX) ][-h]" << endl; return false; } TheMarkerMapConfig.readFromFile(argv[2]); TheMarkerMapConfigFile = argv[2]; TheMarkerSize = stof(cml("-s", "1")); // read from camera or from file if (string(argv[1]) == "live") { TheVideoCapturer.open(0); } else TheVideoCapturer.open(argv[1]); // check video is open if (!TheVideoCapturer.isOpened()) throw std::runtime_error("Could not open video"); // read first image to get the dimensions TheVideoCapturer >> TheInputImage; // read camera parameters if passed if (cml["-c"]) { TheCameraParameters.readFromXMLFile(cml("-c")); TheCameraParameters.resize(TheInputImage.size()); } // prepare the detector string dict = TheMarkerMapConfig .getDictionary(); // see if the dictrionary is already indicated in the configuration file. It should! if (dict.empty()) dict = "ARUCO"; TheMarkerDetector.setDictionary( dict); /// DO NOT FORGET THAT!!! Otherwise, the ARUCO dictionary will be used by default! if (stoi(cml("-corner", "0")) == 0) TheMarkerDetector.setCornerRefinementMethod(MarkerDetector::LINES); else { MarkerDetector::Params params = TheMarkerDetector.getParams(); params._cornerMethod = MarkerDetector::SUBPIX; // search corner subpix in a 5x5 widow area params._subpix_wsize = static_cast<int>((15.f / 2000.f) * float(TheInputImage.cols)); TheMarkerDetector.setParams(params); } // prepare the pose tracker if possible // if the camera parameers are avaiable, and the markerset can be expressed in meters, then go if (TheMarkerMapConfig.isExpressedInPixels() && TheMarkerSize > 0) TheMarkerMapConfig = TheMarkerMapConfig.convertToMeters(TheMarkerSize); cout << "TheCameraParameters.isValid()=" << TheCameraParameters.isValid() << " " << TheMarkerMapConfig.isExpressedInMeters() << endl; if (TheCameraParameters.isValid() && TheMarkerMapConfig.isExpressedInMeters()) TheMSPoseTracker.setParams(TheCameraParameters, TheMarkerMapConfig); // Create gui cv::namedWindow("thres", 1); cv::namedWindow("in", 1); TheMarkerDetector.getThresholdParams(ThresParam1, ThresParam2); iThresParam1 = static_cast<int>(ThresParam1); iThresParam2 = static_cast<int>(ThresParam2); cv::createTrackbar("ThresParam1", "in", &iThresParam1, 13, cvTackBarEvents); cv::createTrackbar("ThresParam2", "in", &iThresParam2, 13, cvTackBarEvents); char key = 0; int index = 0; // capture until press ESC or until the end of the video cout << "Press 's' to start/stop video" << endl; do { TheVideoCapturer.retrieve(TheInputImage); TheInputImage.copyTo(TheInputImageCopy); index++; // number of images captured // Detection of the board vector<aruco::Marker> detected_markers = TheMarkerDetector.detect(TheInputImage); // print the markers detected that belongs to the markerset for (auto idx : TheMarkerMapConfig.getIndices(detected_markers)) detected_markers[idx].draw(TheInputImageCopy, Scalar(0, 0, 255), 2); // detect 3d info if possible if (TheMSPoseTracker.isValid()) { if (TheMSPoseTracker.estimatePose(detected_markers)) { aruco::CvDrawingUtils::draw3dAxis(TheInputImageCopy, TheCameraParameters, TheMSPoseTracker.getRvec(), TheMSPoseTracker.getTvec(), TheMarkerMapConfig[0].getMarkerSize() * 2); frame_pose_map.insert(make_pair(index, TheMSPoseTracker.getRTMatrix())); cout << "pose rt=" << TheMSPoseTracker.getRvec() << " " << TheMSPoseTracker.getTvec() << endl; } } // show input with augmented information and the thresholded image cv::imshow("in", TheInputImageCopy); cv::imshow("thres", TheMarkerDetector.getThresholdedImage()); key = cv::waitKey(waitTime); // wait for key to be pressed processKey(key); } while (key != 27 && TheVideoCapturer.grab()); // save a beatiful pcd file (pcl library) showing the results (you can use pcl_viewer to see it) if (cml["-pcd"]) { savePCDFile(cml("-pcd"), TheMarkerMapConfig, frame_pose_map); } // save the poses to a file in tum rgbd data format if (cml["-poses"]) { savePosesToFile(cml("-poses"), frame_pose_map); } } catch (std::exception& ex) { cout << "Exception :" << ex.what() << endl; } }
int main(int argc,char **argv) { try { if (readArguments (argc,argv)==false) { return 0; } //parse arguments ; //read from camera or from file if (TheInputVideo=="live") { TheVideoCapturer.open(0); waitTime=10; } else TheVideoCapturer.open(TheInputVideo); //check video is open if (!TheVideoCapturer.isOpened()) { cerr<<"Could not open video"<<endl; return -1; } //read first image to get the dimensions TheVideoCapturer>>TheInputImage; //read camera parameters if passed if (TheIntrinsicFile!="") { TheCameraParameters.readFromXMLFile(TheIntrinsicFile); TheCameraParameters.resize(TheInputImage.size()); } //Configure other parameters if (ThePyrDownLevel>0) MDetector.pyrDown(ThePyrDownLevel); //begin copy-paste from http://stackoverflow.com/questions/11550021/converting-a-mat-file-from-matlab-into-cvmat-matrix-in-opencv Mat oneVect; Mat useVecLat; Mat someVects; Mat zeroYzero; string demoFile = "demo.yml"; FileStorage fsDemo( demoFile, FileStorage::READ); fsDemo["oneVect"] >> oneVect; fsDemo["oneVect"] >> useVecLat; fsDemo["oneVect"] >> zeroYzero; fsDemo["someVects"] >> someVects; cout << "Print the contents of oneVect:" << endl; cout << oneVect << endl; fsDemo.release(); //close the file // Declare what you need // FileStorage fileOutt("reading_positions.yml", FileStorage::WRITE); //end copy-paste from http://stackoverflow.com/questions/11550021/converting-a-mat-file-from-matlab-into-cvmat-matrix-in-opencv cout << "an element oneVect:" << endl; cout << oneVect.at<float>(0,1) << endl; // to access the 42 in this YAML: //oneVect: !!opencv-matrix // rows: 1 // cols: 3 // dt: f // data: [ 4, 3, 42, 55] // do oneVect.at<float>(0,2) //end data input //Create gui cv::namedWindow("thres",1); cv::namedWindow("in",1); MDetector.getThresholdParams( ThresParam1,ThresParam2); MDetector.setCornerRefinementMethod(MarkerDetector::LINES); iThresParam1=ThresParam1; iThresParam2=ThresParam2; cv::createTrackbar("ThresParam1", "in",&iThresParam1, 13, cvTackBarEvents); cv::createTrackbar("ThresParam2", "in",&iThresParam2, 13, cvTackBarEvents); char key=0; int index=0; //capture until press ESC or until the end of the video while ( key!=27 && TheVideoCapturer.grab()) { TheVideoCapturer.retrieve( TheInputImage); //copy image index++; //number of images captured double tick = (double)getTickCount();//for checking the speed //Detection of markers in the image passed cout << "q" ; MDetector.detect(TheInputImage,TheMarkers,TheCameraParameters,TheMarkerSize); //note that this function outputs the marker info, for some reason. //chekc the speed by calculating the mean speed of all iterations AvrgTime.first+=((double)getTickCount()-tick)/getTickFrequency(); AvrgTime.second++; //cout<<"Time detection="<<1000*AvrgTime.first/AvrgTime.second<<" milliseconds"<<endl; //print marker info and draw the markers in image TheInputImage.copyTo(TheInputImageCopy); for (unsigned int i=0;i<TheMarkers.size();i++) { cout<<TheMarkers[i].Tvec.at<float>(0,0)<<","<< TheMarkers[i].Tvec.at<float>(0,1)<<","<< TheMarkers[i].Tvec.at<float>(0,2)<<","; // cout<<TheMarkers[i]<<endl; if (TheMarkers[i].id == 605 && 1 == 0) { // THIS WILL NEVER HAPPEN!!! 1 is not zero. Mat R33; cv::Rodrigues(TheMarkers[i].Rvec,R33); cout << R33 << endl; cout << TheMarkers[i].id << endl; for (unsigned int maytr=0;maytr<TheMarkers.size();maytr++) { //take 0 , 1 , 0, inverse transform first, then transform. if (TheMarkers[maytr].id == 500) { zeroYzero.at<float>(0,0) = 0; zeroYzero.at<float>(0,1) = 2; zeroYzero.at<float>(0,2) = 0; zeroYzero.at<float>(0,3) = 0; zeroYzero.at<float>(0,4) = 0; zeroYzero.at<float>(0,5) = 0; cout << zeroYzero << endl; Mat R33for500; cout << TheMarkers[maytr].id<< "food"<< endl; cv::Rodrigues(TheMarkers[maytr].Rvec,R33for500); cout << R33for500 << endl; //cout << TheMarkers[i].id << endl; //R33for500 * R33.t() * zeroYzero; //transpose method //Mat afterDouble; //cout << TheMarkers[maytr].id<< "water"<< endl; //afterDouble = R33for500 * (R33.inv() * zeroYzero); //inversion method //R33for500 * (R33.inv() * zeroYzero); //inversion method //cout << "shelll"<< endl; //cout << afterDouble << endl; //useVecLat.at<float>(0,0) = 0; //useVecLat.at<float>(0,1) = 0; //useVecLat.at<float>(0,2) = 0; //useVecLat.at<float>(0,3) = afterDouble.at<float>(0,0); //useVecLat.at<float>(0,4) = afterDouble.at<float>(0,1); //useVecLat.at<float>(0,5) = afterDouble.at<float>(0,2); //drawVecAtPos(TheInputImageCopy,TheMarkers[maytr],TheCameraParameters,afterDouble); //oneVect); } } } TheMarkers[i].draw(TheInputImageCopy,Scalar(0,0,255),1); //time date stuff std::time_t result = std::time(NULL); //nullptr); std::cout // << std::asctime(std::localtime(&result)) << result; // << " seconds since the Epoch\n"; // fileOutt << "time" << result ; //<< endl; cout<<endl; // <<endl<<endl; } //print other rectangles that contains no valid markers /** for (unsigned int i=0;i<MDetector.getCandidates().size();i++) { aruco::Marker m( MDetector.getCandidates()[i],999); m.draw(TheInputImageCopy,cv::Scalar(255,0,0)); }*/ //draw a 3d cube in each marker if there is 3d info if ( TheCameraParameters.isValid()) for (unsigned int i=0;i<TheMarkers.size();i++) { CvDrawingUtils::draw3dCube(TheInputImageCopy,TheMarkers[i],TheCameraParameters); //Never use this; just reference // CvDrawingUtils::draw3dAxis(TheInputImageCopy,TheMarkers[i],TheCameraParameters); draw3dAxisj(TheInputImageCopy,TheMarkers[i],TheCameraParameters); drawVecAtPos(TheInputImageCopy,TheMarkers[i],TheCameraParameters,oneVect); drawVecsAtPosTesting(TheInputImageCopy,TheMarkers[i],TheCameraParameters,someVects); } //DONE! Easy, right? //show input with augmented information and the thresholded image cv::imshow("in",TheInputImageCopy); cv::imshow("thres",MDetector.getThresholdedImage()); key=cv::waitKey(waitTime);//wait for key to be pressed } // fileOutt.release(); } catch (std::exception &ex) { cout<<"Exception :"<<ex.what()<<endl; } }
int main(int argc,char **argv) { try { if ( readArguments (argc,argv)==false) return 0; //parse arguments TheBoardConfig.readFromFile(TheBoardConfigFile); //read from camera or from file if (TheInputVideo=="live") { TheVideoCapturer.open(0); waitTime=10; } else TheVideoCapturer.open(TheInputVideo); //check video is open if (!TheVideoCapturer.isOpened()) { cerr<<"Could not open video"<<endl; return -1; } //read first image to get the dimensions TheVideoCapturer>>TheInputImage; //Open outputvideo if ( TheOutVideoFilePath!="") VWriter.open(TheOutVideoFilePath,CV_FOURCC('M','J','P','G'),15,TheInputImage.size()); //read camera parameters if passed if (TheIntrinsicFile!="") { TheCameraParameters.readFromXMLFile(TheIntrinsicFile); TheCameraParameters.resize(TheInputImage.size()); } //Create gui cv::namedWindow("thres",1); cv::namedWindow("in",1); TheBoardDetector.setParams(TheBoardConfig,TheCameraParameters,TheMarkerSize); TheBoardDetector.getMarkerDetector().getThresholdParams( ThresParam1,ThresParam2); TheBoardDetector.getMarkerDetector().enableErosion(true);//for chessboards iThresParam1=ThresParam1; iThresParam2=ThresParam2; cv::createTrackbar("ThresParam1", "in",&iThresParam1, 13, cvTackBarEvents); cv::createTrackbar("ThresParam2", "in",&iThresParam2, 13, cvTackBarEvents); char key=0; int index=0; //capture until press ESC or until the end of the video while ( key!=27 && TheVideoCapturer.grab()) { TheVideoCapturer.retrieve( TheInputImage); TheInputImage.copyTo(TheInputImageCopy); index++; //number of images captured double tick = (double)getTickCount();//for checking the speed //Detection of the board float probDetect=TheBoardDetector.detect(TheInputImage); //chekc the speed by calculating the mean speed of all iterations AvrgTime.first+=((double)getTickCount()-tick)/getTickFrequency(); AvrgTime.second++; cout<<"Time detection="<<1000*AvrgTime.first/AvrgTime.second<<" milliseconds"<<endl; //print marker borders for (unsigned int i=0;i<TheBoardDetector.getDetectedMarkers().size();i++) TheBoardDetector.getDetectedMarkers()[i].draw(TheInputImageCopy,Scalar(0,0,255),1); //print board if (TheCameraParameters.isValid()) { if ( probDetect>0.2) { CvDrawingUtils::draw3dAxis( TheInputImageCopy,TheBoardDetector.getDetectedBoard(),TheCameraParameters); //draw3dBoardCube( TheInputImageCopy,TheBoardDetected,TheIntriscCameraMatrix,TheDistorsionCameraParams); } } //DONE! Easy, right? //show input with augmented information and the thresholded image cv::imshow("in",TheInputImageCopy); cv::imshow("thres",TheBoardDetector.getMarkerDetector().getThresholdedImage()); //write to video if required if ( TheOutVideoFilePath!="") { //create a beautiful compiosed image showing the thresholded //first create a small version of the thresholded image cv::Mat smallThres; cv::resize( TheBoardDetector.getMarkerDetector().getThresholdedImage(),smallThres,cvSize(TheInputImageCopy.cols/3,TheInputImageCopy.rows/3)); cv::Mat small3C; cv::cvtColor(smallThres,small3C,CV_GRAY2BGR); cv::Mat roi=TheInputImageCopy(cv::Rect(0,0,TheInputImageCopy.cols/3,TheInputImageCopy.rows/3)); small3C.copyTo(roi); VWriter<<TheInputImageCopy; // cv::imshow("TheInputImageCopy",TheInputImageCopy); } key=cv::waitKey(waitTime);//wait for key to be pressed processKey(key); } } catch (std::exception &ex) { cout<<"Exception :"<<ex.what()<<endl; } }
int main(int argc, char **argv) { try { if (readArguments(argc, argv) == false) { return 0; } // parse arguments // read from camera or from file if (TheInputVideo.find("live") != string::npos) { int vIdx = 0; // check if the :idx is here char cad[100]; if (TheInputVideo.find(":") != string::npos) { std::replace(TheInputVideo.begin(), TheInputVideo.end(), ':', ' '); sscanf(TheInputVideo.c_str(), "%s %d", cad, &vIdx); } cout << "Opening camera index " << vIdx << endl; TheVideoCapturer.open(vIdx); waitTime = 10; } else TheVideoCapturer.open(TheInputVideo); // check video is open if (!TheVideoCapturer.isOpened()) { cerr << "Could not open video" << endl; return -1; } bool isVideoFile = false; if (TheInputVideo.find(".avi") != std::string::npos || TheInputVideo.find("live") != string::npos) isVideoFile = true; // read first image to get the dimensions TheVideoCapturer >> TheInputImage; // read camera parameters if passed if (TheIntrinsicFile != "") { TheCameraParameters.readFromXMLFile(TheIntrinsicFile); TheCameraParameters.resize(TheInputImage.size()); } // Configure other parameters if (ThePyrDownLevel > 0) MDetector.pyrDown(ThePyrDownLevel); // Create gui cv::namedWindow("thres", 1); cv::namedWindow("in", 1); MDetector.setThresholdParams(7, 7); MDetector.setThresholdParamRange(2, 0); // MDetector.enableLockedCornersMethod(true); // MDetector.setCornerRefinementMethod ( MarkerDetector::SUBPIX ); MDetector.getThresholdParams(ThresParam1, ThresParam2); iThresParam1 = ThresParam1; iThresParam2 = ThresParam2; //cv::createTrackbar("ThresParam1", "in", &iThresParam1, 25, cvTackBarEvents); //cv::createTrackbar("ThresParam2", "in", &iThresParam2, 13, cvTackBarEvents); char key = 0; int index = 0; // capture until press ESC or until the end of the video TheVideoCapturer.retrieve(TheInputImage); cv::Size sz = TheInputImage.size(); MDetector.createCudaBuffers(sz.width, sz.height); do { // copy image index++; // number of images captured double tick = (double)getTickCount(); // for checking the speed // Detection of markers in the image passed MDetector.detect(TheInputImage, TheMarkers, TheCameraParameters, TheMarkerSize); // chekc the speed by calculating the mean speed of all iterations AvrgTime.first += ((double)getTickCount() - tick) / getTickFrequency(); AvrgTime.second++; cout << "\rTime detection=" << 1000 * AvrgTime.first / AvrgTime.second << " milliseconds nmarkers=" << TheMarkers.size() << std::flush; // print marker info and draw the markers in image TheInputImage.copyTo(TheInputImageCopy); for (unsigned int i = 0; i < TheMarkers.size(); i++) { cout << endl << TheMarkers[i]; TheMarkers[i].draw(TheInputImageCopy, Scalar(0, 0, 255), 1); } if (TheMarkers.size() != 0) cout << endl; // print other rectangles that contains no valid markers /** for (unsigned int i=0;i<MDetector.getCandidates().size();i++) { aruco::Marker m( MDetector.getCandidates()[i],999); m.draw(TheInputImageCopy,cv::Scalar(255,0,0)); }*/ // draw a 3d cube in each marker if there is 3d info if (TheCameraParameters.isValid()) for (unsigned int i = 0; i < TheMarkers.size(); i++) { CvDrawingUtils::draw3dCube(TheInputImageCopy, TheMarkers[i], TheCameraParameters); CvDrawingUtils::draw3dAxis(TheInputImageCopy, TheMarkers[i], TheCameraParameters); } // DONE! Easy, right? // show input with augmented information and the thresholded image cv::imshow("in", TheInputImageCopy); cv::imshow("thres", MDetector.getThresholdedImage()); //cv::imshow("thres_gpu", MDetector.getThresholdedImageGPU()); key = cv::waitKey(waitTime); // wait for key to be pressed if (isVideoFile) TheVideoCapturer.retrieve(TheInputImage); } while (key != 27 && (TheVideoCapturer.grab() || !isVideoFile)); } catch (std::exception &ex) { cout << "Exception :" << ex.what() << endl; } }
int main(int argc,char **argv) { try { if (readArguments (argc,argv)==false) { return 0; } //parse arguments ; //read from camera or from file if (TheInputVideo=="live") { TheVideoCapturer.open(0); waitTime=10; } else TheVideoCapturer.open(TheInputVideo); //check video is open if (!TheVideoCapturer.isOpened()) { cerr<<"Could not open video"<<endl; return -1; } //read first image to get the dimensions TheVideoCapturer>>TheInputImage; //read camera parameters if passed if (TheIntrinsicFile!="") { TheCameraParameters.readFromXMLFile(TheIntrinsicFile); TheCameraParameters.resize(TheInputImage.size()); } //Configure other parameters if (ThePyrDownLevel>0) MDetector.pyrDown(ThePyrDownLevel); //Create gui MDetector.getThresholdParams( ThresParam1,ThresParam2); MDetector.setCornerRefinementMethod(MarkerDetector::LINES); /* cv::namedWindow("thres",1); cv::namedWindow("in",1); iThresParam1=ThresParam1; iThresParam2=ThresParam2; cv::createTrackbar("ThresParam1", "in",&iThresParam1, 13, cvTackBarEvents); cv::createTrackbar("ThresParam2", "in",&iThresParam2, 13, cvTackBarEvents); */ char key=0; int index=0; //capture until press ESC or until the end of the video while ( key!=27 && TheVideoCapturer.grab() ) // && index <= 50) { TheVideoCapturer.retrieve( TheInputImage); //copy image index++; //number of images captured double tick = (double)getTickCount();//for checking the speed //Detection of markers in the image passed MDetector.detect(TheInputImage,TheMarkers,TheCameraParameters,TheMarkerSize); //chekc the speed by calculating the mean speed of all iterations AvrgTime.first+=((double)getTickCount()-tick)/getTickFrequency(); AvrgTime.second++; //cout<<"Time detection="<<1000*AvrgTime.first/AvrgTime.second<<" milliseconds"<<endl; //print marker info and draw the markers in image TheInputImage.copyTo(TheInputImageCopy); for (unsigned int i=0;i<TheMarkers.size();i++) { if (AllMarkers.count( TheMarkers[i].id ) == 0) AllMarkers[TheMarkers[i].id] = map<int,Marker>(); AllMarkers[TheMarkers[i].id][index] = TheMarkers[i]; cout<<index<<endl; cout<<TheMarkers[i]<<endl; TheMarkers[i].draw(TheInputImageCopy,Scalar(0,0,255),1); } //print other rectangles that contains no valid markers /** for (unsigned int i=0;i<MDetector.getCandidates().size();i++) { aruco::Marker m( MDetector.getCandidates()[i],999); m.draw(TheInputImageCopy,cv::Scalar(255,0,0)); }*/ //draw a 3d cube in each marker if there is 3d info if ( TheCameraParameters.isValid()) for (unsigned int i=0;i<TheMarkers.size();i++) { CvDrawingUtils::draw3dCube(TheInputImageCopy,TheMarkers[i],TheCameraParameters); CvDrawingUtils::draw3dAxis(TheInputImageCopy,TheMarkers[i],TheCameraParameters); } //DONE! Easy, right? cout<<endl<<endl<<endl; //show input with augmented information and the thresholded image //cv::imshow("in",TheInputImageCopy); //cv::imshow("thres",MDetector.getThresholdedImage()); //key=cv::waitKey(waitTime);//wait for key to be pressed } lastFrame = index; } catch (std::exception &ex) { cout<<"Exception :"<<ex.what()<<endl; } cout << "All done."<< endl; map<int, Markers>::const_iterator i; for( i = AllMarkers.begin(); i != AllMarkers.end(); ++i ) { int markerId = (*i).first; map<int, Marker> markers = (*i).second; int frameCount = markers.size(); cout << "frameCount = " << frameCount << endl; std::vector<double> x(frameCount); std::vector<double> m0x(frameCount); std::vector<double> m0y(frameCount); std::vector<double> m1x(frameCount); std::vector<double> m1y(frameCount); std::vector<double> m2x(frameCount); std::vector<double> m2y(frameCount); std::vector<double> m3x(frameCount); std::vector<double> m3y(frameCount); std::vector<double> tx(frameCount); std::vector<double> ty(frameCount); std::vector<double> tz(frameCount); std::vector<double> rx(frameCount); std::vector<double> ry(frameCount); std::vector<double> rz(frameCount); map<int, Marker>::const_iterator j; int index = 0; for( j = markers.begin(); j != markers.end(); ++j, index++ ) { int frameIndex = (*j).first; Marker marker = (*j).second; x[index] = frameIndex; m0x[index] = marker[0].x; m0y[index] = marker[0].y; m1x[index] = marker[1].x; m1y[index] = marker[1].y; m2x[index] = marker[2].x; m2y[index] = marker[2].y; m3x[index] = marker[3].x; m3y[index] = marker[3].y; tx[index] = marker.Tvec.ptr<float>(0)[0]; ty[index] = marker.Tvec.ptr<float>(0)[1]; tz[index] = marker.Tvec.ptr<float>(0)[2]; rx[index] = marker.Rvec.ptr<float>(0)[0]; ry[index] = marker.Rvec.ptr<float>(0)[1]; rz[index] = marker.Rvec.ptr<float>(0)[2]; cout << frameIndex << endl; } #define SPLINE(VAR) gsl_spline *spline_ ## VAR = gsl_spline_alloc (gsl_interp_cspline, frameCount); gsl_spline_init (spline_ ## VAR, &x[0], &VAR[0], frameCount) SPLINE(m0x); SPLINE(m0y); SPLINE(m1x); SPLINE(m1y); SPLINE(m2x); SPLINE(m2y); SPLINE(m3x); SPLINE(m3y); SPLINE(tx); SPLINE(ty); SPLINE(tz); SPLINE(rx); SPLINE(ry); SPLINE(rz); for( index = 0; index < lastFrame; index++ ) { double m0x = gsl_spline_eval (spline_m0x, index, NULL); double m0y = gsl_spline_eval (spline_m0y, index, NULL); double m1x = gsl_spline_eval (spline_m1x, index, NULL); double m1y = gsl_spline_eval (spline_m1y, index, NULL); double m2x = gsl_spline_eval (spline_m2x, index, NULL); double m2y = gsl_spline_eval (spline_m2y, index, NULL); double m3x = gsl_spline_eval (spline_m3x, index, NULL); double m3y = gsl_spline_eval (spline_m3y, index, NULL); double tx = gsl_spline_eval (spline_tx, index, NULL); double ty = gsl_spline_eval (spline_ty, index, NULL); double tz = gsl_spline_eval (spline_tz, index, NULL); double rx = gsl_spline_eval (spline_rx, index, NULL); double ry = gsl_spline_eval (spline_ry, index, NULL); double rz = gsl_spline_eval (spline_rz, index, NULL); cv::Point2f m0 = cv::Point2f(m0x,m0y); cv::Point2f m1 = cv::Point2f(m1x,m1y); cv::Point2f m2 = cv::Point2f(m2x,m2y); cv::Point2f m3 = cv::Point2f(m3x,m3y); std::vector<cv::Point2f> corners(4); corners[0] = m0; corners[1] = m1; corners[2] = m2; corners[3] = m3; Marker interpolated = Marker(corners, markerId); interpolated.Rvec.create(3,1,CV_32FC1); interpolated.Tvec.create(3,1,CV_32FC1); interpolated.Tvec.at<float>(0,0) = tx; interpolated.Tvec.at<float>(1,0) = ty; interpolated.Tvec.at<float>(2,0) = tz; interpolated.Rvec.at<float>(0,0) = rx; interpolated.Rvec.at<float>(1,0) = ry; interpolated.Rvec.at<float>(2,0) = rz; cout << index << endl; cout << interpolated << endl; } gsl_spline_free (spline_m0x); gsl_spline_free (spline_m0y); gsl_spline_free (spline_m1x); gsl_spline_free (spline_m1y); gsl_spline_free (spline_m2x); gsl_spline_free (spline_m2y); gsl_spline_free (spline_m3x); gsl_spline_free (spline_m3y); gsl_spline_free (spline_tx); gsl_spline_free (spline_ty); gsl_spline_free (spline_tz); gsl_spline_free (spline_rx); gsl_spline_free (spline_ry); gsl_spline_free (spline_rz); //map<int, Marker>::const_iterator j; //cout << "id = " << markerId << endl; } //cout << TheFrames << endl; }
int main(int argc,char **argv) { try { if (readArguments (argc,argv)==false) { return 0; } //parse arguments ; //read from camera or from file if (TheInputVideo=="live") { TheVideoCapturer.open(0); waitTime=10; } else TheVideoCapturer.open(TheInputVideo); //check video is open if (!TheVideoCapturer.isOpened()) { cerr<<"Could not open video"<<endl; return -1; } //read first image to get the dimensions TheVideoCapturer>>TheInputImage; //read camera parameters if passed if (TheIntrinsicFile!="") { TheCameraParameters.readFromXMLFile(TheIntrinsicFile); TheCameraParameters.resize(TheInputImage.size()); } //Configure other parameters if (ThePyrDownLevel>0) MDetector.pyrDown(ThePyrDownLevel); //Create gui cv::namedWindow("thres",1); cv::namedWindow("in",1); MDetector.getThresholdParams( ThresParam1,ThresParam2); MDetector.setCornerRefinementMethod(MarkerDetector::LINES); iThresParam1=ThresParam1; iThresParam2=ThresParam2; cv::createTrackbar("ThresParam1", "in",&iThresParam1, 13, cvTackBarEvents); cv::createTrackbar("ThresParam2", "in",&iThresParam2, 13, cvTackBarEvents); char key=0; int index=0; //capture until press ESC or until the end of the video while ( key!=27 && TheVideoCapturer.grab()) { TheVideoCapturer.retrieve( TheInputImage); //copy image index++; //number of images captured double tick = (double)getTickCount();//for checking the speed //Detection of markers in the image passed MDetector.detect(TheInputImage,TheMarkers,TheCameraParameters,TheMarkerSize); //chekc the speed by calculating the mean speed of all iterations AvrgTime.first+=((double)getTickCount()-tick)/getTickFrequency(); AvrgTime.second++; cout<<"Time detection="<<1000*AvrgTime.first/AvrgTime.second<<" milliseconds"<<endl; //print marker info and draw the markers in image TheInputImage.copyTo(TheInputImageCopy); for (unsigned int i=0;i<TheMarkers.size();i++) { cout<<TheMarkers[i]<<endl; TheMarkers[i].draw(TheInputImageCopy,Scalar(0,0,255),1); } //print other rectangles that contains no valid markers /** for (unsigned int i=0;i<MDetector.getCandidates().size();i++) { aruco::Marker m( MDetector.getCandidates()[i],999); m.draw(TheInputImageCopy,cv::Scalar(255,0,0)); }*/ //draw a 3d cube in each marker if there is 3d info if ( TheCameraParameters.isValid()) for (unsigned int i=0;i<TheMarkers.size();i++) { CvDrawingUtils::draw3dCube(TheInputImageCopy,TheMarkers[i],TheCameraParameters); CvDrawingUtils::draw3dAxis(TheInputImageCopy,TheMarkers[i],TheCameraParameters); } //DONE! Easy, right? cout<<endl<<endl<<endl; //show input with augmented information and the thresholded image cv::imshow("in",TheInputImageCopy); cv::imshow("thres",MDetector.getThresholdedImage()); key=cv::waitKey(waitTime);//wait for key to be pressed } } catch (std::exception &ex) { cout<<"Exception :"<<ex.what()<<endl; } }