/* By downloading, copying, installing or using the software you agree to this license. If you do not agree to this license, do not download, install, copy or use the software. License Agreement For Open Source Computer Vision Library (3-clause BSD License) Copyright (C) 2013, OpenCV Foundation, all rights reserved. Third party copyrights are property of their respective owners. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the names of the copyright holders nor the names of the contributors may be used to endorse or promote products derived from this software without specific prior written permission. This software is provided by the copyright holders and contributors "as is" and any express or implied warranties, including, but not limited to, the implied warranties of merchantability and fitness for a particular purpose are disclaimed. In no event shall copyright holders or contributors be liable for any direct, indirect, incidental, special, exemplary, or consequential damages (including, but not limited to, procurement of substitute goods or services; loss of use, data, or profits; or business interruption) however caused and on any theory of liability, whether in contract, strict liability, or tort (including negligence or otherwise) arising in any way out of the use of this software, even if advised of the possibility of such damage. */ #include #include #include #include #include #include #include using namespace std; using namespace cv; namespace { const char* about = "Calibration using a ChArUco board\n" " To capture a frame for calibration, press 'c',\n" " If input comes from video, press any key for next frame\n" " To finish capturing, press 'ESC' key and calibration starts.\n"; const char* keys = "{w | | Number of squares in X direction }" "{h | | Number of squares in Y direction }" "{sl | | Square side length (in meters) }" "{ml | | Marker side length (in meters) }" "{d | | dictionary: DICT_4X4_50=0, DICT_4X4_100=1, DICT_4X4_250=2," "DICT_4X4_1000=3, DICT_5X5_50=4, DICT_5X5_100=5, DICT_5X5_250=6, DICT_5X5_1000=7, " "DICT_6X6_50=8, DICT_6X6_100=9, DICT_6X6_250=10, DICT_6X6_1000=11, DICT_7X7_50=12," "DICT_7X7_100=13, DICT_7X7_250=14, DICT_7X7_1000=15, DICT_ARUCO_ORIGINAL = 16}" "{@outfile | | Output file with calibrated camera parameters }" "{v | | Input from video file, if ommited, input comes from camera }" "{ci | 0 | Camera id if input doesnt come from video (-v) }" "{dp | | File of marker detector parameters }" "{rs | false | Apply refind strategy }" "{zt | false | Assume zero tangential distortion }" "{a | | Fix aspect ratio (fx/fy) to this value }" "{pc | false | Fix the principal point at the center }" "{sc | false | Show detected chessboard corners after calibration }"; } /** */ static bool readDetectorParameters(string filename, Ptr ¶ms) { FileStorage fs(filename, FileStorage::READ); if(!fs.isOpened()) return false; fs["adaptiveThreshWinSizeMin"] >> params->adaptiveThreshWinSizeMin; fs["adaptiveThreshWinSizeMax"] >> params->adaptiveThreshWinSizeMax; fs["adaptiveThreshWinSizeStep"] >> params->adaptiveThreshWinSizeStep; fs["adaptiveThreshConstant"] >> params->adaptiveThreshConstant; fs["minMarkerPerimeterRate"] >> params->minMarkerPerimeterRate; fs["maxMarkerPerimeterRate"] >> params->maxMarkerPerimeterRate; fs["polygonalApproxAccuracyRate"] >> params->polygonalApproxAccuracyRate; fs["minCornerDistanceRate"] >> params->minCornerDistanceRate; fs["minDistanceToBorder"] >> params->minDistanceToBorder; fs["minMarkerDistanceRate"] >> params->minMarkerDistanceRate; fs["cornerRefinementMethod"] >> params->cornerRefinementMethod; fs["cornerRefinementWinSize"] >> params->cornerRefinementWinSize; fs["cornerRefinementMaxIterations"] >> params->cornerRefinementMaxIterations; fs["cornerRefinementMinAccuracy"] >> params->cornerRefinementMinAccuracy; fs["markerBorderBits"] >> params->markerBorderBits; fs["perspectiveRemovePixelPerCell"] >> params->perspectiveRemovePixelPerCell; fs["perspectiveRemoveIgnoredMarginPerCell"] >> params->perspectiveRemoveIgnoredMarginPerCell; fs["maxErroneousBitsInBorderRate"] >> params->maxErroneousBitsInBorderRate; fs["minOtsuStdDev"] >> params->minOtsuStdDev; fs["errorCorrectionRate"] >> params->errorCorrectionRate; return true; } /** */ static bool saveCameraParams(const string &filename, Size imageSize, float aspectRatio, int flags, const Mat &cameraMatrix, const Mat &distCoeffs, double totalAvgErr) { FileStorage fs(filename, FileStorage::WRITE); if(!fs.isOpened()) return false; time_t tt; time(&tt); struct tm *t2 = localtime(&tt); char buf[1024]; strftime(buf, sizeof(buf) - 1, "%c", t2); fs << "calibration_time" << buf; fs << "image_width" << imageSize.width; fs << "image_height" << imageSize.height; if(flags & CALIB_FIX_ASPECT_RATIO) fs << "aspectRatio" << aspectRatio; if(flags != 0) { sprintf(buf, "flags: %s%s%s%s", flags & CALIB_USE_INTRINSIC_GUESS ? "+use_intrinsic_guess" : "", flags & CALIB_FIX_ASPECT_RATIO ? "+fix_aspectRatio" : "", flags & CALIB_FIX_PRINCIPAL_POINT ? "+fix_principal_point" : "", flags & CALIB_ZERO_TANGENT_DIST ? "+zero_tangent_dist" : ""); } fs << "flags" << flags; fs << "camera_matrix" << cameraMatrix; fs << "distortion_coefficients" << distCoeffs; fs << "avg_reprojection_error" << totalAvgErr; return true; } /** */ int main(int argc, char *argv[]) { CommandLineParser parser(argc, argv, keys); parser.about(about); if(argc < 7) { parser.printMessage(); return 0; } int squaresX = parser.get("w"); int squaresY = parser.get("h"); float squareLength = parser.get("sl"); float markerLength = parser.get("ml"); int dictionaryId = parser.get("d"); string outputFile = parser.get(0); bool showChessboardCorners = parser.get("sc"); int calibrationFlags = 0; float aspectRatio = 1; if(parser.has("a")) { calibrationFlags |= CALIB_FIX_ASPECT_RATIO; aspectRatio = parser.get("a"); } if(parser.get("zt")) calibrationFlags |= CALIB_ZERO_TANGENT_DIST; if(parser.get("pc")) calibrationFlags |= CALIB_FIX_PRINCIPAL_POINT; Ptr detectorParams = aruco::DetectorParameters::create(); if(parser.has("dp")) { bool readOk = readDetectorParameters(parser.get("dp"), detectorParams); if(!readOk) { cerr << "Invalid detector parameters file" << endl; return 0; } } bool refindStrategy = parser.get("rs"); int camId = parser.get("ci"); String video; if(parser.has("v")) { video = parser.get("v"); } if(!parser.check()) { parser.printErrors(); return 0; } VideoCapture inputVideo; int waitTime; if(!video.empty()) { inputVideo.open(video); waitTime = 0; } else { inputVideo.open(camId); waitTime = 10; } Ptr dictionary = aruco::getPredefinedDictionary(aruco::PREDEFINED_DICTIONARY_NAME(dictionaryId)); // create charuco board object Ptr charucoboard = aruco::CharucoBoard::create(squaresX, squaresY, squareLength, markerLength, dictionary); Ptr board = charucoboard.staticCast(); // collect data from each frame vector< vector< vector< Point2f > > > allCorners; vector< vector< int > > allIds; vector< Mat > allImgs; Size imgSize; while(inputVideo.grab()) { Mat image, imageCopy; inputVideo.retrieve(image); vector< int > ids; vector< vector< Point2f > > corners, rejected; // detect markers aruco::detectMarkers(image, dictionary, corners, ids, detectorParams, rejected); // refind strategy to detect more markers if(refindStrategy) aruco::refineDetectedMarkers(image, board, corners, ids, rejected); // interpolate charuco corners Mat currentCharucoCorners, currentCharucoIds; if(ids.size() > 0) aruco::interpolateCornersCharuco(corners, ids, image, charucoboard, currentCharucoCorners, currentCharucoIds); // draw results image.copyTo(imageCopy); if(ids.size() > 0) aruco::drawDetectedMarkers(imageCopy, corners); if(currentCharucoCorners.total() > 0) aruco::drawDetectedCornersCharuco(imageCopy, currentCharucoCorners, currentCharucoIds); putText(imageCopy, "Press 'c' to add current frame. 'ESC' to finish and calibrate", Point(10, 20), FONT_HERSHEY_SIMPLEX, 0.5, Scalar(255, 0, 0), 2); imshow("out", imageCopy); char key = (char)waitKey(waitTime); if(key == 27) break; if(key == 'c' && ids.size() > 0) { cout << "Frame captured" << endl; allCorners.push_back(corners); allIds.push_back(ids); allImgs.push_back(image); imgSize = image.size(); } } if(allIds.size() < 1) { cerr << "Not enough captures for calibration" << endl; return 0; } Mat cameraMatrix, distCoeffs; vector< Mat > rvecs, tvecs; double repError; if(calibrationFlags & CALIB_FIX_ASPECT_RATIO) { cameraMatrix = Mat::eye(3, 3, CV_64F); cameraMatrix.at< double >(0, 0) = aspectRatio; } // prepare data for calibration vector< vector< Point2f > > allCornersConcatenated; vector< int > allIdsConcatenated; vector< int > markerCounterPerFrame; markerCounterPerFrame.reserve(allCorners.size()); for(unsigned int i = 0; i < allCorners.size(); i++) { markerCounterPerFrame.push_back((int)allCorners[i].size()); for(unsigned int j = 0; j < allCorners[i].size(); j++) { allCornersConcatenated.push_back(allCorners[i][j]); allIdsConcatenated.push_back(allIds[i][j]); } } // calibrate camera using aruco markers double arucoRepErr; arucoRepErr = aruco::calibrateCameraAruco(allCornersConcatenated, allIdsConcatenated, markerCounterPerFrame, board, imgSize, cameraMatrix, distCoeffs, noArray(), noArray(), calibrationFlags); // prepare data for charuco calibration int nFrames = (int)allCorners.size(); vector< Mat > allCharucoCorners; vector< Mat > allCharucoIds; vector< Mat > filteredImages; allCharucoCorners.reserve(nFrames); allCharucoIds.reserve(nFrames); for(int i = 0; i < nFrames; i++) { // interpolate using camera parameters Mat currentCharucoCorners, currentCharucoIds; aruco::interpolateCornersCharuco(allCorners[i], allIds[i], allImgs[i], charucoboard, currentCharucoCorners, currentCharucoIds, cameraMatrix, distCoeffs); allCharucoCorners.push_back(currentCharucoCorners); allCharucoIds.push_back(currentCharucoIds); filteredImages.push_back(allImgs[i]); } if(allCharucoCorners.size() < 4) { cerr << "Not enough corners for calibration" << endl; return 0; } // calibrate camera using charuco repError = aruco::calibrateCameraCharuco(allCharucoCorners, allCharucoIds, charucoboard, imgSize, cameraMatrix, distCoeffs, rvecs, tvecs, calibrationFlags); bool saveOk = saveCameraParams(outputFile, imgSize, aspectRatio, calibrationFlags, cameraMatrix, distCoeffs, repError); if(!saveOk) { cerr << "Cannot save output file" << endl; return 0; } cout << "Rep Error: " << repError << endl; cout << "Rep Error Aruco: " << arucoRepErr << endl; cout << "Calibration saved to " << outputFile << endl; // show interpolated charuco corners for debugging if(showChessboardCorners) { for(unsigned int frame = 0; frame < filteredImages.size(); frame++) { Mat imageCopy = filteredImages[frame].clone(); if(allIds[frame].size() > 0) { if(allCharucoCorners[frame].total() > 0) { aruco::drawDetectedCornersCharuco( imageCopy, allCharucoCorners[frame], allCharucoIds[frame]); } } imshow("out", imageCopy); char key = (char)waitKey(0); if(key == 27) break; } } return 0; }