示例#1
0
文件: main.cpp 项目: alerk/TestOpenCV
int getFirePixelNumber(Mat aFrame) {
    const int ROI_WIDTH = 40;
    const int ROI_HEIGHT = 30;
    unsigned int currentWidth = 0, currentHeight = 0;
    unsigned int width, height;
    std::vector<std::vector<cv::Point> > contours;
    //Mat roi;
    Rect roi;
    width = aFrame.cols;
    height = aFrame.rows;

    Mat YCrCbFrame;
    Mat YChannel, CrChannel, CbChannel;
    Mat Y_Cb, Cr_Cb;
    Mat colorMask;

    //check for input frame
    if(aFrame.empty())
    {
        return -1;
    }
    //---------------detect moving pixel------------//
    //       using BackgroundSubstractMOG2 			//
    //----------------------------------------------//
    bg.operator ()(aFrame, front);
    bg.getBackgroundImage(back);
    //cv::erode(front,front, cv::Mat());
    //cv::dilate(front, front, cv::Mat());
    cv::medianBlur(front, front, 5);
    cv::findContours(front,contours,CV_RETR_EXTERNAL,CV_CHAIN_APPROX_NONE);
    std::vector<std::vector<cv::Point> > contours_poly( contours.size() );
    vector<Rect> boundRect( contours.size() );
    vector<Point2f>center( contours.size() );
    vector<float>radius( contours.size() );

    for(unsigned int i = 0; i < contours.size(); i++ )
    {
        cv::approxPolyDP( contours[i], contours_poly[i], 3.0, true );
        boundRect[i] = boundingRect( Mat(contours_poly[i]) );
        cv::minEnclosingCircle( contours_poly[i], center[i], radius[i] );
    }

    for(unsigned int i = 0; i< contours.size(); i++ )
    {
        Scalar color = Scalar( 255,255,255 );
        //params:	  input   output       contourIdx	color    thickness
        drawContours( front, contours_poly,    i,       color,   CV_FILLED, 8, vector<Vec4i>(), 0, Point() );
    }

    //----detect fire color----//
    //-------------------------------------------------------------------//
    //	pixel = fire color when											 //
    //			valueY > valueCb &&										 //
    //			valueCr > valueCb &&									 //
    //			(valueY > meanY && valueCr > meanCr && valueCb < meanCb) //
    //-------------------------------------------------------------------//

    //get YCrCb channel
    cvtColor(aFrame, YCrCbFrame, CV_BGR2YCrCb);
    vector<Mat> channels(3);
    split(YCrCbFrame, channels);
    YChannel = channels[0];
    CrChannel = channels[1];
    CbChannel = channels[2];

    //calculate mean of 3 channels: => for further use
//	unsigned char Y_mean, Cr_mean, Cb_mean;
//	Y_mean = (unsigned char)mean(YChannel)[0];
//	Cr_mean = (unsigned char)mean(CrChannel)[0];
//	Cb_mean = (unsigned char)mean(CbChannel)[0];

    colorMask = Mat(aFrame.rows, aFrame.cols, CV_8UC1);
    Y_Cb  = Mat(aFrame.rows, aFrame.cols, CV_8UC1);//YChannel minus CbChannel
    Cr_Cb = Mat(aFrame.rows, aFrame.cols, CV_8UC1);//CrChannel minus CbChannel
    subtract(YChannel, CbChannel, Y_Cb); threshold(Y_Cb, Y_Cb, 10, 255, THRESH_BINARY);
    subtract(CrChannel, CbChannel, Cr_Cb);threshold(Cr_Cb, Cr_Cb, 10, 255, THRESH_BINARY);

    //colorMask = front & Y_Cb & Y_Cr
    bitwise_and(front, Y_Cb, colorMask);
    bitwise_and(colorMask, Cr_Cb, colorMask);

    for(currentWidth = 0; currentWidth < width; currentWidth+=ROI_WIDTH)
    {
        for(currentHeight = 0; currentHeight < height; currentHeight+=ROI_HEIGHT)
        {
            roi = Rect(currentWidth, currentHeight, ROI_WIDTH, ROI_HEIGHT);
            cv::Mat testArea = colorMask(roi);
            int fireCount = countNonZero(testArea);
            if(fireCount > 10)
            {
                cv::Mat roi_draw = aFrame(roi);
                cv::Mat color(roi_draw.size(), CV_8UC3, cv::Scalar (0,125,125));
                double alpha = 0.5;
                cv::addWeighted(color, alpha, roi_draw, 1.0-alpha, 0.0, roi_draw);
            }
        }
    }

    int fireCount = countNonZero(colorMask);

    cvtColor(front, front, CV_GRAY2BGR);
    cvtColor(Y_Cb, Y_Cb, CV_GRAY2BGR);
    cvtColor(Cr_Cb, Cr_Cb, CV_GRAY2BGR);
    cvtColor(colorMask, colorMask, CV_GRAY2BGR);

    char wName[25];
    sprintf(&(wName[0]),"Frames");
    cvShowManyImages(wName, aFrame.cols, aFrame.rows, 5, (unsigned char*)aFrame.data, (unsigned char*)front.data, (unsigned char*)Y_Cb.data, (unsigned char*)Cr_Cb.data, (unsigned char*)colorMask.data);
//	imshow(wName, frame);
//    if(fireCount>fireThreshold)
//    {
//        //count the frame that contains firePixel surpass threshold
//        std::cout << "Fired" << std::endl;
//    }
//    else
//    {
//        std::cout << "Not fired" << std::endl;
//    }
    return fireCount;
}
void WayFinderApp::update()
{
    if(getElapsedFrames() % FRAME_COUNT_THRESHOLD == 0) {
        detected = false;

        // TODO: Consider converting capture to grayscale or blurring then thresholding to improve performance.
        if(capture && capture->checkNewFrame()) {
            frame = toOcv(capture->getSurface());
            //cv::Mat frameGray, frameBlurred, frameThresh, foreGray, backGray;
            //cvtColor(frame, frameGray, CV_BGR2GRAY);
            int blurAmount = 10;
            //cv::blur(frame, frameBlurred, cv::Size(blurAmount, blurAmount));
            //threshold(frameBlurred, frameThresh, 100, 255, CV_THRESH_BINARY);

            // Get all contours.
            //bg.operator()(frameThresh,fore);
            bg.operator()(frame, fore);
            bg.getBackgroundImage(back);
            cv::erode(fore, fore, cv::Mat());
            cv::dilate(fore, fore, cv::Mat());
            cv::findContours(fore, contours, CV_RETR_EXTERNAL, CV_CHAIN_APPROX_NONE);

            // Get largest contour: http://stackoverflow.com/questions/15012073/opencv-draw-draw-contours-of-2-largest-objects
            unsigned largestIndex = 0;
            unsigned largestContour = 0;
            for(unsigned i = 0; i < contours.size(); i++) {
                if(contours[i].size() > largestContour) {
                    largestContour = contours[i].size();
                    largestIndex = i;
                }
            }

            vector<std::vector<cv::Point>> hack;
            cv::Rect rect;
            cv::Point center;

            if(contours.size() > 0) {
                hack.push_back(contours[largestIndex]);

                // Find bounding rectangle for largest countour.
                rect = boundingRect(contours[largestIndex]);

                // Make sure the blog is large enough to be a track-worthy.
                println("Rext area = " + boost::lexical_cast<std::string>(rect.area()));
                if(rect.area() >= 5000) { // TODO: Tweak this value.
                    // Get center of rectangle.
                    center = cv::Point(
                                 rect.x + (rect.width / 2),
                                 rect.y + (rect.height / 2)
                             );

                    // Show guide.
                    spotlightCenter2D.x = (float)center.x;
                    spotlightCenter2D.y = (float)center.y;
                    spotlightCenter3D.x = (float)center.x;
                    spotlightCenter3D.y = (float)center.y;
                    //spotlightRadius = (rect.width + rect.y) / 2;
                    detected = true;
                }
            }

            // When debug mode is off, the background should be black.
            if(debugView) {
                if(contours.size() > 0) {
                    cv::drawContours(frame, contours, -1, cv::Scalar(0, 0, 255), 2);
                    cv::drawContours(frame, hack, -1, cv::Scalar(255, 0, 0), 2);
                    rectangle(frame, rect, cv::Scalar(0, 255, 0), 3);
                    circle(frame, center, 10, cv::Scalar(0, 255, 0), 3);
                }
                mTexture = gl::Texture(fromOcv(frame));
            }
        }

        // TODO: Create control panel for all inputs.
    }
}
示例#3
0
extern "C" void getbg(int rows, int cols, unsigned char *bgD) {
    cv::Mat bg = cv::Mat(rows, cols, CV_8UC3, bgD);
    mog.getBackgroundImage(bg);
}
示例#4
0
/**
 * Detect people using background segmentation and contours
 * BSN2013
 */
static vector<cv::Mat> detectPeopleSegment(cv::Mat image) {
	vector<cv::Mat> points;

	// convert to HSV
	cv::Mat imageHSV;
	cv::cvtColor(image, imageHSV, CV_BGR2HSV);
	vector<cv::Mat> imageHSVSlices;
	cv::split(imageHSV, imageHSVSlices);
	//cv::threshold(imageHSVSlices[0], imageHSVSlices[0], 160, 200, cv::THRESH_BINARY);

	// background subtraction
	cv::Mat fgMask;
	bgmodel(image, fgMask, learningRate);
	// tidy foreground mask
	cv::GaussianBlur(fgMask, fgMask, cv::Size(1, 1), 0, 0);
	int erosionSize = 5;
	cv::Mat element = cv::getStructuringElement( cv::MORPH_ELLIPSE,
		cv::Size(2*erosionSize+1, 2*erosionSize+1),
		cv::Point( erosionSize, erosionSize ));
	cv::dilate(fgMask, fgMask, element);
	cv::erode(fgMask, fgMask, element);
	cv::erode(fgMask, fgMask, element);
	cv::dilate(fgMask, fgMask, element);
	cv::Mat background;
	bgmodel.getBackgroundImage(background);
	//cv::imshow("back", background);

	// subtract background from original image
	cv::Mat foreground;
	//cv::not
	cv::threshold(fgMask, fgMask, 128, 255, cv::THRESH_BINARY);
	image.copyTo(foreground, fgMask);
	cv::imshow("fg", fgMask);
	cv::imshow("fore", foreground);

	// edge information
	int lowThreshold = 100;
	int ratio = 3;
	int kernelSize = 3;
	cv::Mat imageCanny;
	cv::Canny(foreground, imageCanny, lowThreshold, lowThreshold*ratio, kernelSize);

	// weight map and weighted-gradient image
	// apply Gaussian filter (size = 9 and sigma = 1.5) to edge information from foreground image
	// create Gaussian filter
	// weight map
	cv::Mat weightMap;
	cv::GaussianBlur(imageCanny, weightMap, cv::Size(9, 9), 1.5, 1.5);
	// gradient image
	cv::Mat imageGray;
	cv::cvtColor(image, imageGray, CV_BGR2GRAY);
	cv::Mat imageGradient;
	cv::Mat imageGradientX;
	cv::Mat imageGradientY;
	cv::Mat imageAbsGradientX;
	cv::Mat imageAbsGradientY;
	cv::Sobel(imageGray, imageGradientX, CV_16S, 1, 0, 3, 1, 0, cv::BORDER_DEFAULT);
	cv::Sobel(imageGray, imageGradientY, CV_16S, 0, 1, 3, 1, 0, cv::BORDER_DEFAULT);
	cv::convertScaleAbs(imageGradientX, imageAbsGradientX);
	cv::convertScaleAbs(imageGradientY, imageAbsGradientY);
	cv::addWeighted(imageAbsGradientX, 0.5, imageAbsGradientY, 0.5, 0, imageGradient);
	// weighted-gradient image
	cv::Mat weightedGradient;
	cv::Mat colourWeightMap;
	weightedGradient = imageGradient.mul(weightMap);

	// object (body) contours
	vector< vector<cv::Point> > objectContours;
	vector<cv::Vec4i> objectHierarchy;
	cv::findContours(fgMask, objectContours, objectHierarchy, CV_RETR_TREE, CV_CHAIN_APPROX_SIMPLE, cv::Point(0, 0));

	// bodies and heads
	// store index of detected body contours and position of head
	vector<int> bodies;
	vector<cv::Point2f> headCenter;
	vector<float> headRadius;

	// detect big bodies
	for (int i = 0; i < objectContours.size(); i++) {
		// if contour is too big
		if (getContourRadius(objectContours[i]) > BODYSIZE*2) {
			// increment merged counter
			numMerged++;
			cout << "Merged object" << endl;

			// TODO cut down to size
			// TODO consider just slicing it
			// process contour by eroding it
			cv::Mat largeContour = cv::Mat::zeros(imageCanny.size(), CV_8UC3);
			drawContours(largeContour, objectContours, i, colourRed, CV_FILLED, 8, objectHierarchy, 0, cv::Point());
			// erode until large contour becomes 2+
			vector< vector<cv::Point> > largeContours;
			vector<cv::Vec4i> largeHierarchy;
			do {
				cv::erode(largeContour, largeContour, element);
				cv::Canny(largeContour, largeContour, lowThreshold, lowThreshold*ratio, kernelSize);
				cv::findContours(largeContour, largeContours, largeHierarchy, CV_RETR_TREE, CV_CHAIN_APPROX_SIMPLE, cv::Point(0, 0));
			} while (largeContours.size() == 1); // || (largeContours.size() == 1 && getContourRadius(largeContours[0]) >= BODYSIZE)); // TODO potential infinite bug here
			if (largeContours.size() > 1) {
				// increment split counter
				numSplit++;
				cout << "Split object" << endl;
			}
			else if (largeContours.size() == 1) {
				// increment unsplit counter
				numUnsplit++;
				cout << "No split - size still 1" << endl;
			}
			for (int j = 0; j < largeContours.size(); j++) {
				objectContours.push_back(largeContours[j]);
			}
		}
	}
	
	cv::Mat bodiesHeads = cv::Mat::zeros(image.size(), CV_8UC3);
	// detect bodies
	for (int i = 0; i < objectContours.size(); i++) {
		if (isBody(objectContours[i])) {
			// predict head position
			cv::Point2f defaultHeadCenter;
			// body bounding box
			cv::RotatedRect minBodyRect;
			minBodyRect = cv::minAreaRect(cv::Mat(objectContours[i]));
			// body bounding circle radius
			float headOffset = getContourRadius(objectContours[i]); //*0.7;
			// image centre
			cv::Point2f imageCentre(image.size().width/2, image.size().height/2);
			// find gradient
			float m = (minBodyRect.center.y - imageCentre.y)/(minBodyRect.center.x - imageCentre.x);
			// find angle
			double angle;
			if (minBodyRect.center.x <= imageCentre.x && minBodyRect.center.y < imageCentre.y) {
				// top left quad
				angle = atan((imageCentre.x - minBodyRect.center.x)/(imageCentre.y - minBodyRect.center.y));
			}
			else if (minBodyRect.center.x <= imageCentre.x) {
				// bottom left quad
				angle = PI - atan((imageCentre.x - minBodyRect.center.x)/(minBodyRect.center.y - imageCentre.y));
			}
			else if (minBodyRect.center.x > imageCentre.x && minBodyRect.center.y > imageCentre.y) {
				// bottom right quad
				angle = PI + atan((minBodyRect.center.x - imageCentre.x)/(minBodyRect.center.y - imageCentre.y));
			}
			else {
				// top right quad
				angle = 2*PI - atan((minBodyRect.center.x - imageCentre.x)/(imageCentre.y - minBodyRect.center.y));
			}
			do {
				headOffset *= 0.7;
				defaultHeadCenter = cv::Point2f(minBodyRect.center.x - headOffset * sin(angle), minBodyRect.center.y - headOffset * cos(angle));
			} while (cv::pointPolygonTest(objectContours[i], defaultHeadCenter, true) <= 0 && headOffset >= 1);
			// store body and head if body big enough for head
			if (headOffset >= 1) {
				// store body
				bodies.push_back(i);
				//angle = angle * 180/PI;
				headCenter.push_back(defaultHeadCenter);
				headRadius.push_back(0); // default head size
				// get detailed contours of body
				cv::Mat bodyMask = cv::Mat::zeros(image.size(), CV_8UC1);
				drawContours(bodyMask, objectContours, i, colourWhite, CV_FILLED, 8, objectHierarchy, 0, cv::Point());
				//cv::floodFill(bodyMask, cv::Point2i(0, 0), cv::Scalar(1));
				cv::Mat body;
				image.copyTo(body, bodyMask);
				//cv::imshow("B", body);
				// body edges
				cv::Mat bodyCanny;
				cv::Canny(body, bodyCanny, lowThreshold, lowThreshold*ratio, kernelSize);
				// weight map
				cv::Mat bodyWeightMap;
				cv::GaussianBlur(bodyCanny, bodyWeightMap, cv::Size(9, 9), 1.5, 1.5);
				// gradient image
				cv::Mat bodyGray;
				cv::cvtColor(body, bodyGray, CV_BGR2GRAY);
				cv::Mat bodyGradient;
				cv::Mat bodyGradientX;
				cv::Mat bodyGradientY;
				cv::Mat bodyAbsGradientX;
				cv::Mat bodyAbsGradientY;
				cv::Sobel(bodyGray, bodyGradientX, CV_16S, 1, 0, 3, 1, 0, cv::BORDER_DEFAULT);
				cv::Sobel(bodyGray, bodyGradientY, CV_16S, 0, 1, 3, 1, 0, cv::BORDER_DEFAULT);
				cv::convertScaleAbs(bodyGradientX, bodyAbsGradientX);
				cv::convertScaleAbs(bodyGradientY, bodyAbsGradientY);
				cv::addWeighted(bodyAbsGradientX, 0.5, bodyAbsGradientY, 0.5, 0, bodyGradient);
				// weighted-gradient image
				cv::Mat bodyWeightedGradient;
				bodyWeightedGradient = bodyGradient.mul(bodyWeightMap);
				// body contours
				vector< vector<cv::Point> > bodyContours;
				vector<cv::Vec4i> bodyHierarchy;
				cv::findContours(bodyWeightedGradient, bodyContours, bodyHierarchy, CV_RETR_TREE, CV_CHAIN_APPROX_SIMPLE, cv::Point(0, 0));
				// detect head
				for (int j = 0; j < bodyContours.size(); j++) {
					// process contour by eroding it
					cv::Mat aContour = cv::Mat::zeros(image.size(), CV_8UC3);
					drawContours(aContour, bodyContours, j, colourWhite, CV_FILLED, 8, bodyHierarchy, 0, cv::Point());
					drawContours(bodiesHeads, bodyContours, j, colourWhite, 2, 8, bodyHierarchy, 0, cv::Point());
					cv::erode(aContour, aContour, element);
					//cv::erode(aContour, aContour, element);
					//cv::dilate(aContour, aContour, element);
					cv::Canny(aContour, aContour, lowThreshold, lowThreshold*ratio, kernelSize);
					vector< vector<cv::Point> > subContours;
					vector<cv::Vec4i> subHierarchy;
					cv::findContours(aContour, subContours, subHierarchy, CV_RETR_TREE, CV_CHAIN_APPROX_SIMPLE, cv::Point(0, 0));
					//
					for (int k = 0; k < subContours.size(); k++) {
						//cv::drawContours(imageContours, subContours, k, cv::Scalar(0, 255, 0), 2, 8, subHierarchy, 0, cv::Point());
						if (isHead(subContours[k], objectContours[i])) {
							vector<cv::Point> contourPoly;
							cv::Point2f center;
							float radius;
							if (subContours.size() > 1) {
								approxPolyDP(cv::Mat(subContours[k]), contourPoly, 3, true);
							}
							else {
								approxPolyDP(cv::Mat(bodyContours[j]), contourPoly, 3, true);
							}
							minEnclosingCircle((cv::Mat)contourPoly, center, radius);
							float distanceOld = euclideanDistance(headCenter[headCenter.size() - 1], defaultHeadCenter);
							float distanceNew = euclideanDistance(center, defaultHeadCenter);
							if (headRadius[headRadius.size() - 1] == 0 || (distanceOld > 0 && distanceNew < distanceOld)) {
								// store first detected head or store if it is a better detection
								headCenter[headCenter.size() - 1] = center;
								headRadius[headRadius.size() - 1] = radius;
							}
						}
					}
				}
				if (headRadius[headRadius.size() - 1] == 0) {
					headRadius[headRadius.size() - 1] = 10;
				}
			}
		}
	}

	// draw bodies and heads
	//cv::Mat bodiesHeads = cv::Mat::zeros(image.size(), CV_8UC3);
	for (int i = 0; i < bodies.size(); i++) {
		// draw body
		cv::Scalar colour = cv::Scalar(rng.uniform(0, 255), rng.uniform(0, 255), rng.uniform(0, 255));
		drawContours(foreground, objectContours, bodies[i], colour, 2, 8, objectHierarchy, 0, cv::Point());
		circle(foreground, headCenter[i], (int)headRadius[i], colour, 2, 8, 0);
		// body bounding box
		cv::RotatedRect bodyRect;
		bodyRect = cv::minAreaRect(cv::Mat(objectContours[bodies[i]]));
		// output
		cout << imageNum;
		cout << "," << headCenter[i].x << "," << headCenter[i].y << "," << headRadius[i]; // head info
		cout << "," << bodyRect.center.x << "," << bodyRect.center.y;
		cout << "," << cv::contourArea(objectContours[bodies[i]]);
		cout << endl;
		// output points
		cv::Mat point(2, 1, CV_32FC1);
		point.at<float>(0) = headCenter[i].x;
		point.at<float>(1) = headCenter[i].y;
		points.push_back(point);
	}

	// increment frame counter
	numFrames++;

	cv::imshow("Original", image);
	//cv::imshow("Hue", imageHSVSlices[0]);
	//cv::imshow("Saturation", imageHSVSlices[1]);
	//cv::imshow("Value", imageHSVSlices[2]);
	cv::imshow("fgMask", fgMask);
	cv::imshow("Foreground", foreground);
	cv::imshow("Canny", imageCanny);
	cv::imshow("WeightMap", weightMap);
	cv::imshow("Gradient Image", imageGradient);
	cv::imshow("Weighted-Gradient Image", weightedGradient);
	//cv::imshow("Contours", imageContours);
	cv::imshow("Body & Head", bodiesHeads);
	cvWaitKey(delay); //5
	
	return points;
}