// This file is part of OpenCV project. // It is subject to the license terms in the LICENSE file found in the top-level directory // of this distribution and at http://opencv.org/license.html. #include "frameProcessor.hpp" #include "rotationConverters.hpp" #include #include #include #include #include #include #include using namespace calib; #define VIDEO_TEXT_SIZE 4 #define POINT_SIZE 5 static cv::SimpleBlobDetector::Params getDetectorParams() { cv::SimpleBlobDetector::Params detectorParams; detectorParams.thresholdStep = 40; detectorParams.minThreshold = 20; detectorParams.maxThreshold = 500; detectorParams.minRepeatability = 2; detectorParams.minDistBetweenBlobs = 5; detectorParams.filterByColor = true; detectorParams.blobColor = 0; detectorParams.filterByArea = true; detectorParams.minArea = 5; detectorParams.maxArea = 5000; detectorParams.filterByCircularity = false; detectorParams.minCircularity = 0.8f; detectorParams.maxCircularity = std::numeric_limits::max(); detectorParams.filterByInertia = true; detectorParams.minInertiaRatio = 0.1f; detectorParams.maxInertiaRatio = std::numeric_limits::max(); detectorParams.filterByConvexity = true; detectorParams.minConvexity = 0.8f; detectorParams.maxConvexity = std::numeric_limits::max(); return detectorParams; } FrameProcessor::~FrameProcessor() { } bool CalibProcessor::detectAndParseChessboard(const cv::Mat &frame) { int chessBoardFlags = cv::CALIB_CB_ADAPTIVE_THRESH | cv::CALIB_CB_NORMALIZE_IMAGE | cv::CALIB_CB_FAST_CHECK; bool isTemplateFound = cv::findChessboardCorners(frame, mBoardSize, mCurrentImagePoints, chessBoardFlags); if (isTemplateFound) { cv::Mat viewGray; cv::cvtColor(frame, viewGray, cv::COLOR_BGR2GRAY); cv::cornerSubPix(viewGray, mCurrentImagePoints, cv::Size(11,11), cv::Size(-1,-1), cv::TermCriteria( cv::TermCriteria::EPS+cv::TermCriteria::COUNT, 30, 0.1 )); cv::drawChessboardCorners(frame, mBoardSize, cv::Mat(mCurrentImagePoints), isTemplateFound); mTemplateLocations.insert(mTemplateLocations.begin(), mCurrentImagePoints[0]); } return isTemplateFound; } bool CalibProcessor::detectAndParseChAruco(const cv::Mat &frame) { #ifdef HAVE_OPENCV_ARUCO cv::Ptr board = mCharucoBoard.staticCast(); std::vector > corners, rejected; std::vector ids; cv::aruco::detectMarkers(frame, cv::makePtr(mArucoDictionary), corners, ids, cv::makePtr(), rejected); cv::aruco::refineDetectedMarkers(frame, board, corners, ids, rejected); cv::Mat currentCharucoCorners, currentCharucoIds; if(ids.size() > 0) cv::aruco::interpolateCornersCharuco(corners, ids, frame, mCharucoBoard, currentCharucoCorners, currentCharucoIds); if(ids.size() > 0) cv::aruco::drawDetectedMarkers(frame, corners); if(currentCharucoCorners.total() > 3) { float centerX = 0, centerY = 0; for (int i = 0; i < currentCharucoCorners.size[0]; i++) { centerX += currentCharucoCorners.at(i, 0); centerY += currentCharucoCorners.at(i, 1); } centerX /= currentCharucoCorners.size[0]; centerY /= currentCharucoCorners.size[0]; mTemplateLocations.insert(mTemplateLocations.begin(), cv::Point2f(centerX, centerY)); cv::aruco::drawDetectedCornersCharuco(frame, currentCharucoCorners, currentCharucoIds); mCurrentCharucoCorners = currentCharucoCorners; mCurrentCharucoIds = currentCharucoIds; return true; } #else CV_UNUSED(frame); #endif return false; } bool CalibProcessor::detectAndParseCircles(const cv::Mat &frame) { bool isTemplateFound = findCirclesGrid(frame, mBoardSize, mCurrentImagePoints, cv::CALIB_CB_SYMMETRIC_GRID, mBlobDetectorPtr); if(isTemplateFound) { mTemplateLocations.insert(mTemplateLocations.begin(), mCurrentImagePoints[0]); cv::drawChessboardCorners(frame, mBoardSize, cv::Mat(mCurrentImagePoints), isTemplateFound); } return isTemplateFound; } bool CalibProcessor::detectAndParseACircles(const cv::Mat &frame) { bool isTemplateFound = findCirclesGrid(frame, mBoardSize, mCurrentImagePoints, cv::CALIB_CB_ASYMMETRIC_GRID, mBlobDetectorPtr); if(isTemplateFound) { mTemplateLocations.insert(mTemplateLocations.begin(), mCurrentImagePoints[0]); cv::drawChessboardCorners(frame, mBoardSize, cv::Mat(mCurrentImagePoints), isTemplateFound); } return isTemplateFound; } bool CalibProcessor::detectAndParseDualACircles(const cv::Mat &frame) { std::vector blackPointbuf; cv::Mat invertedView; cv::bitwise_not(frame, invertedView); bool isWhiteGridFound = cv::findCirclesGrid(frame, mBoardSize, mCurrentImagePoints, cv::CALIB_CB_ASYMMETRIC_GRID, mBlobDetectorPtr); if(!isWhiteGridFound) return false; bool isBlackGridFound = cv::findCirclesGrid(invertedView, mBoardSize, blackPointbuf, cv::CALIB_CB_ASYMMETRIC_GRID, mBlobDetectorPtr); if(!isBlackGridFound) { mCurrentImagePoints.clear(); return false; } cv::drawChessboardCorners(frame, mBoardSize, cv::Mat(mCurrentImagePoints), isWhiteGridFound); cv::drawChessboardCorners(frame, mBoardSize, cv::Mat(blackPointbuf), isBlackGridFound); mCurrentImagePoints.insert(mCurrentImagePoints.end(), blackPointbuf.begin(), blackPointbuf.end()); mTemplateLocations.insert(mTemplateLocations.begin(), mCurrentImagePoints[0]); return true; } void CalibProcessor::saveFrameData() { std::vector objectPoints; switch(mBoardType) { case Chessboard: objectPoints.reserve(mBoardSize.height*mBoardSize.width); for( int i = 0; i < mBoardSize.height; ++i ) for( int j = 0; j < mBoardSize.width; ++j ) objectPoints.push_back(cv::Point3f(j*mSquareSize, i*mSquareSize, 0)); mCalibData->imagePoints.push_back(mCurrentImagePoints); mCalibData->objectPoints.push_back(objectPoints); break; case chAruco: mCalibData->allCharucoCorners.push_back(mCurrentCharucoCorners); mCalibData->allCharucoIds.push_back(mCurrentCharucoIds); break; case CirclesGrid: objectPoints.reserve(mBoardSize.height*mBoardSize.width); for( int i = 0; i < mBoardSize.height; i++ ) for( int j = 0; j < mBoardSize.width; j++ ) objectPoints.push_back(cv::Point3f(j*mSquareSize, i*mSquareSize, 0)); mCalibData->imagePoints.push_back(mCurrentImagePoints); mCalibData->objectPoints.push_back(objectPoints); break; case AcirclesGrid: objectPoints.reserve(mBoardSize.height*mBoardSize.width); for( int i = 0; i < mBoardSize.height; i++ ) for( int j = 0; j < mBoardSize.width; j++ ) objectPoints.push_back(cv::Point3f((2*j + i % 2)*mSquareSize, i*mSquareSize, 0)); mCalibData->imagePoints.push_back(mCurrentImagePoints); mCalibData->objectPoints.push_back(objectPoints); break; case DoubleAcirclesGrid: { float gridCenterX = (2*((float)mBoardSize.width - 1) + 1)*mSquareSize + mTemplDist / 2; float gridCenterY = (mBoardSize.height - 1)*mSquareSize / 2; objectPoints.reserve(2*mBoardSize.height*mBoardSize.width); //white part for( int i = 0; i < mBoardSize.height; i++ ) for( int j = 0; j < mBoardSize.width; j++ ) objectPoints.push_back( cv::Point3f(-float((2*j + i % 2)*mSquareSize + mTemplDist + (2*(mBoardSize.width - 1) + 1)*mSquareSize - gridCenterX), -float(i*mSquareSize) - gridCenterY, 0)); //black part for( int i = 0; i < mBoardSize.height; i++ ) for( int j = 0; j < mBoardSize.width; j++ ) objectPoints.push_back(cv::Point3f(-float((2*j + i % 2)*mSquareSize - gridCenterX), -float(i*mSquareSize) - gridCenterY, 0)); mCalibData->imagePoints.push_back(mCurrentImagePoints); mCalibData->objectPoints.push_back(objectPoints); } break; } } void CalibProcessor::showCaptureMessage(const cv::Mat& frame, const std::string &message) { cv::Point textOrigin(100, 100); double textSize = VIDEO_TEXT_SIZE * frame.cols / (double) IMAGE_MAX_WIDTH; cv::bitwise_not(frame, frame); cv::putText(frame, message, textOrigin, 1, textSize, cv::Scalar(0,0,255), 2, cv::LINE_AA); cv::Mat resized; if (std::fabs(mZoom - 1.) > 0.001f) { cv::resize(frame, resized, cv::Size(), mZoom, mZoom); } else { resized = frame; } cv::imshow(mainWindowName, resized); cv::waitKey(300); } bool CalibProcessor::checkLastFrame() { bool isFrameBad = false; cv::Mat tmpCamMatrix; const double badAngleThresh = 40; if(!mCalibData->cameraMatrix.total()) { tmpCamMatrix = cv::Mat::eye(3, 3, CV_64F); tmpCamMatrix.at(0,0) = 20000; tmpCamMatrix.at(1,1) = 20000; tmpCamMatrix.at(0,2) = mCalibData->imageSize.height/2; tmpCamMatrix.at(1,2) = mCalibData->imageSize.width/2; } else mCalibData->cameraMatrix.copyTo(tmpCamMatrix); if(mBoardType != chAruco) { cv::Mat r, t, angles; cv::solvePnP(mCalibData->objectPoints.back(), mCurrentImagePoints, tmpCamMatrix, mCalibData->distCoeffs, r, t); RodriguesToEuler(r, angles, CALIB_DEGREES); if(fabs(angles.at(0)) > badAngleThresh || fabs(angles.at(1)) > badAngleThresh) { mCalibData->objectPoints.pop_back(); mCalibData->imagePoints.pop_back(); isFrameBad = true; } } else { #ifdef HAVE_OPENCV_ARUCO cv::Mat r, t, angles; std::vector allObjPoints; allObjPoints.reserve(mCurrentCharucoIds.total()); for(size_t i = 0; i < mCurrentCharucoIds.total(); i++) { int pointID = mCurrentCharucoIds.at((int)i); CV_Assert(pointID >= 0 && pointID < (int)mCharucoBoard->getChessboardCorners().size()); allObjPoints.push_back(mCharucoBoard->getChessboardCorners()[pointID]); } cv::solvePnP(allObjPoints, mCurrentCharucoCorners, tmpCamMatrix, mCalibData->distCoeffs, r, t); RodriguesToEuler(r, angles, CALIB_DEGREES); if(180.0 - fabs(angles.at(0)) > badAngleThresh || fabs(angles.at(1)) > badAngleThresh) { isFrameBad = true; mCalibData->allCharucoCorners.pop_back(); mCalibData->allCharucoIds.pop_back(); } #endif } return isFrameBad; } CalibProcessor::CalibProcessor(cv::Ptr data, captureParameters &capParams) : mCalibData(data), mBoardType(capParams.board), mBoardSize(capParams.boardSize) { mCapuredFrames = 0; mNeededFramesNum = capParams.calibrationStep; mDelayBetweenCaptures = static_cast(capParams.captureDelay * capParams.fps); mMaxTemplateOffset = std::sqrt(static_cast(mCalibData->imageSize.height * mCalibData->imageSize.height) + static_cast(mCalibData->imageSize.width * mCalibData->imageSize.width)) / 20.0; mSquareSize = capParams.squareSize; mTemplDist = capParams.templDst; mSaveFrames = capParams.saveFrames; mZoom = capParams.zoom; switch(mBoardType) { case chAruco: #ifdef HAVE_OPENCV_ARUCO mArucoDictionary = cv::aruco::getPredefinedDictionary(cv::aruco::PredefinedDictionaryType(capParams.charucoDictName)); mCharucoBoard = cv::aruco::CharucoBoard::create(mBoardSize.width, mBoardSize.height, capParams.charucoSquareLength, capParams.charucoMarkerSize, mArucoDictionary); #endif break; case CirclesGrid: case AcirclesGrid: mBlobDetectorPtr = cv::SimpleBlobDetector::create(); break; case DoubleAcirclesGrid: mBlobDetectorPtr = cv::SimpleBlobDetector::create(getDetectorParams()); break; case Chessboard: break; } } cv::Mat CalibProcessor::processFrame(const cv::Mat &frame) { cv::Mat frameCopy; cv::Mat frameCopyToSave; frame.copyTo(frameCopy); bool isTemplateFound = false; mCurrentImagePoints.clear(); if(mSaveFrames) frame.copyTo(frameCopyToSave); switch(mBoardType) { case Chessboard: isTemplateFound = detectAndParseChessboard(frameCopy); break; case chAruco: isTemplateFound = detectAndParseChAruco(frameCopy); break; case CirclesGrid: isTemplateFound = detectAndParseCircles(frameCopy); break; case AcirclesGrid: isTemplateFound = detectAndParseACircles(frameCopy); break; case DoubleAcirclesGrid: isTemplateFound = detectAndParseDualACircles(frameCopy); break; } if(mTemplateLocations.size() > mDelayBetweenCaptures) mTemplateLocations.pop_back(); if(mTemplateLocations.size() == mDelayBetweenCaptures && isTemplateFound) { if(cv::norm(mTemplateLocations.front() - mTemplateLocations.back()) < mMaxTemplateOffset) { saveFrameData(); bool isFrameBad = checkLastFrame(); if (!isFrameBad) { std::string displayMessage = cv::format("Frame # %zu captured", std::max(mCalibData->imagePoints.size(), mCalibData->allCharucoCorners.size())); if(!showOverlayMessage(displayMessage)) showCaptureMessage(frame, displayMessage); if(mSaveFrames) mCalibData->allFrames.push_back(frameCopyToSave); mCapuredFrames++; } else { std::string displayMessage = "Frame rejected"; if(!showOverlayMessage(displayMessage)) showCaptureMessage(frame, displayMessage); } mTemplateLocations.clear(); mTemplateLocations.reserve(mDelayBetweenCaptures); } } return frameCopy; } bool CalibProcessor::isProcessed() const { if(mCapuredFrames < mNeededFramesNum) return false; else return true; } void CalibProcessor::resetState() { mCapuredFrames = 0; mTemplateLocations.clear(); } CalibProcessor::~CalibProcessor() { } //////////////////////////////////////////// void ShowProcessor::drawBoard(cv::Mat &img, cv::InputArray points) { cv::Mat tmpView = cv::Mat::zeros(img.rows, img.cols, CV_8UC3); std::vector templateHull; std::vector poly; cv::convexHull(points, templateHull); poly.resize(templateHull.size()); for(size_t i=0; i >::iterator it = mCalibdata->imagePoints.begin(); it != mCalibdata->imagePoints.end(); ++it) for(std::vector::iterator pointIt = (*it).begin(); pointIt != (*it).end(); ++pointIt) cv::circle(frame, *pointIt, POINT_SIZE, cv::Scalar(0, 255, 0), 1, cv::LINE_AA); else for(std::vector::iterator it = mCalibdata->allCharucoCorners.begin(); it != mCalibdata->allCharucoCorners.end(); ++it) for(int i = 0; i < (*it).size[0]; i++) cv::circle(frame, cv::Point((int)(*it).at(i, 0), (int)(*it).at(i, 1)), POINT_SIZE, cv::Scalar(0, 255, 0), 1, cv::LINE_AA); } ShowProcessor::ShowProcessor(cv::Ptr data, cv::Ptr controller, TemplateType board) : mCalibdata(data), mController(controller), mBoardType(board) { mNeedUndistort = true; mVisMode = Grid; mGridViewScale = 0.5; mTextSize = VIDEO_TEXT_SIZE; } cv::Mat ShowProcessor::processFrame(const cv::Mat &frame) { if (!mCalibdata->cameraMatrix.empty() && !mCalibdata->distCoeffs.empty()) { mTextSize = VIDEO_TEXT_SIZE * (double) frame.cols / IMAGE_MAX_WIDTH; cv::Scalar textColor = cv::Scalar(0,0,255); cv::Mat frameCopy; if (mNeedUndistort && mController->getFramesNumberState()) { if(mVisMode == Grid) drawGridPoints(frame); cv::remap(frame, frameCopy, mCalibdata->undistMap1, mCalibdata->undistMap2, cv::INTER_LINEAR); int baseLine = 100; cv::Size textSize = cv::getTextSize("Undistorted view", 1, mTextSize, 2, &baseLine); cv::Point textOrigin(baseLine, frame.rows - (int)(2.5*textSize.height)); cv::putText(frameCopy, "Undistorted view", textOrigin, 1, mTextSize, textColor, 2, cv::LINE_AA); } else { frame.copyTo(frameCopy); if(mVisMode == Grid) drawGridPoints(frameCopy); } std::string displayMessage; if(mCalibdata->stdDeviations.at(0) == 0) displayMessage = cv::format("F = %d RMS = %.3f", (int)mCalibdata->cameraMatrix.at(0,0), mCalibdata->totalAvgErr); else displayMessage = cv::format("Fx = %d Fy = %d RMS = %.3f", (int)mCalibdata->cameraMatrix.at(0,0), (int)mCalibdata->cameraMatrix.at(1,1), mCalibdata->totalAvgErr); if(mController->getRMSState() && mController->getFramesNumberState()) displayMessage.append(" OK"); int baseLine = 100; cv::Size textSize = cv::getTextSize(displayMessage, 1, mTextSize - 1, 2, &baseLine); cv::Point textOrigin = cv::Point(baseLine, 2*textSize.height); cv::putText(frameCopy, displayMessage, textOrigin, 1, mTextSize - 1, textColor, 2, cv::LINE_AA); if(mCalibdata->stdDeviations.at(0) == 0) displayMessage = cv::format("DF = %.2f", mCalibdata->stdDeviations.at(1)*sigmaMult); else displayMessage = cv::format("DFx = %.2f DFy = %.2f", mCalibdata->stdDeviations.at(0)*sigmaMult, mCalibdata->stdDeviations.at(1)*sigmaMult); if(mController->getConfidenceIntrervalsState() && mController->getFramesNumberState()) displayMessage.append(" OK"); cv::putText(frameCopy, displayMessage, cv::Point(baseLine, 4*textSize.height), 1, mTextSize - 1, textColor, 2, cv::LINE_AA); if(mController->getCommonCalibrationState()) { displayMessage = cv::format("Calibration is done"); cv::putText(frameCopy, displayMessage, cv::Point(baseLine, 6*textSize.height), 1, mTextSize - 1, textColor, 2, cv::LINE_AA); } int calibFlags = mController->getNewFlags(); displayMessage = ""; if(!(calibFlags & cv::CALIB_FIX_ASPECT_RATIO)) displayMessage.append(cv::format("AR=%.3f ", mCalibdata->cameraMatrix.at(0,0)/mCalibdata->cameraMatrix.at(1,1))); if(calibFlags & cv::CALIB_ZERO_TANGENT_DIST) displayMessage.append("TD=0 "); displayMessage.append(cv::format("K1=%.2f K2=%.2f K3=%.2f", mCalibdata->distCoeffs.at(0), mCalibdata->distCoeffs.at(1), mCalibdata->distCoeffs.at(4))); cv::putText(frameCopy, displayMessage, cv::Point(baseLine, frameCopy.rows - (int)(1.5*textSize.height)), 1, mTextSize - 1, textColor, 2, cv::LINE_AA); return frameCopy; } return frame; } bool ShowProcessor::isProcessed() const { return false; } void ShowProcessor::resetState() { } void ShowProcessor::setVisualizationMode(visualisationMode mode) { mVisMode = mode; } void ShowProcessor::switchVisualizationMode() { if(mVisMode == Grid) { mVisMode = Window; updateBoardsView(); } else { mVisMode = Grid; cv::destroyWindow(gridWindowName); } } void ShowProcessor::clearBoardsView() { cv::imshow(gridWindowName, cv::Mat()); } void ShowProcessor::updateBoardsView() { if(mVisMode == Window) { cv::Size originSize = mCalibdata->imageSize; cv::Mat altGridView = cv::Mat::zeros((int)(originSize.height*mGridViewScale), (int)(originSize.width*mGridViewScale), CV_8UC3); if(mBoardType != chAruco) for(std::vector >::iterator it = mCalibdata->imagePoints.begin(); it != mCalibdata->imagePoints.end(); ++it) if(mBoardType != DoubleAcirclesGrid) drawBoard(altGridView, *it); else { size_t pointsNum = (*it).size()/2; std::vector points(pointsNum); std::copy((*it).begin(), (*it).begin() + pointsNum, points.begin()); drawBoard(altGridView, points); std::copy((*it).begin() + pointsNum, (*it).begin() + 2*pointsNum, points.begin()); drawBoard(altGridView, points); } else for(std::vector::iterator it = mCalibdata->allCharucoCorners.begin(); it != mCalibdata->allCharucoCorners.end(); ++it) drawBoard(altGridView, *it); cv::imshow(gridWindowName, altGridView); } } void ShowProcessor::switchUndistort() { mNeedUndistort = !mNeedUndistort; } void ShowProcessor::setUndistort(bool isEnabled) { mNeedUndistort = isEnabled; } ShowProcessor::~ShowProcessor() { }