示例#1
0
void RenderContourBounds(CVPipeline * pipe)
{
	rng = cv::RNG(5553);
	for (int i = 0; i < pipe->contours.Size(); ++i)
	{
		CVContour * contour = &pipe->contours[i];
		cv::Scalar color;
		switch(contour->contourClass)
		{
			case ContourClass::FINGERTIP: 
				color = cv::Scalar(255, 0, 0);	
				break;
			case ContourClass::FINGER: 
				color = cv::Scalar(0, 255, 0);	
				break;
			default: color = cv::Scalar(rng.uniform(0,225), rng.uniform(0,225), rng.uniform(0,255));
		}
		switch(contour->boundingType)
		{
			case BoundingType::ELLIPSE:
				// ellipse
				ellipse(pipe->output, contour->boundingEllipse, color, 2, 8 );
				break;
			case BoundingType::RECT: 
			{
				// rotated rectangle
				cv::Point2f rect_points[4]; 
				contour->boundingRect.points( rect_points );
				for( int j = 0; j < 4; j++ )
					line(pipe->output, rect_points[j], rect_points[(j+1)%4], color, 1, 8 );
				break;
			}
		}
	}
}
示例#2
0
 Plane()
 {
     n[0] = rng.uniform(-0.5, 0.5);
     n[1] = rng.uniform(-0.5, 0.5);
     n[2] = -0.3; //rng.uniform(-1.f, 0.5f);
     n = n / cv::norm(n);
     set_d(rng.uniform(-2.0, 0.6));
 }
示例#3
0
void RenderPolygons(CVPipeline * pipe)
{
	/// Use same random seed every time to avoid rainbow hell..
	rng = cv::RNG(12345);
	for (int i = 0; i < pipe->approximatedPolygons.size(); ++i)
	{			
		cv::Scalar color = cv::Scalar(rng.uniform(0,255), rng.uniform(0,255), rng.uniform(0,255));
		cv::drawContours(pipe->output, pipe->approximatedPolygons, i, color, 2, 8, pipe->contourHierarchy, 0, cv::Point());
	}
}
示例#4
0
const cv::Vec3b Brush::get_color(const cv::Point center, const cv::Mat& reference_image, const Style& style) const {
    cv::Vec3b color = reference_image.at<cv::Vec3b>(center);
    color[0] = clamp(color[0] + color[0] * (rng.uniform(-0.5, 0.5) * style.blue_jitter()));
    color[1] = clamp(color[1] + color[1] * (rng.uniform(-0.5, 0.5) * style.green_jitter()));
    color[2] = clamp(color[2] + color[2] * (rng.uniform(-0.5, 0.5) * style.red_jitter()));
    cv::cvtColor(color, color, CV_RGB2HSV);
    color[0] = clamp(color[0] + color[0] * (rng.uniform(-0.5, 0.5) * style.hue_jitter()));
    color[1] = clamp(color[1] + color[1] * (rng.uniform(-0.5, 0.5) * style.saturation_jitter()));
    color[2] = clamp(color[2] + color[2] * (rng.uniform(-0.5, 0.5) * style.value_jitter()));
    cv::cvtColor(color, color, CV_HSV2RGB);
    return color;
}
void cannyDetector(cv::Mat src, cv::Mat &imgMap)
{

	/*Obsolete version for detection of colored contours... date : 	*/

	int ratio = 3;
	int kernel_size = 3;
	cv::Mat srcGray, srcHsv, cannyOutput;
	std::vector<std::vector<cv::Point> > contours;

	// from color to gray
	cv::cvtColor(src, srcGray, cv::COLOR_BGR2GRAY);
	// from color to hsv
	cv::cvtColor(src, srcHsv, cv::COLOR_BGR2HSV); 

	/// Reduce noise with a kernel 3x3
	cv::blur( srcGray, srcGray, cv::Size(3,3) );

	/// Canny detector
	cv::Canny( srcGray, cannyOutput, lowThreshold, lowThreshold*ratio, kernel_size );

	/// Find contours
	cv::findContours(cannyOutput, contours, CV_RETR_EXTERNAL, CV_CHAIN_APPROX_SIMPLE);

	// Select orange contours
	imgMap = cv::Mat::zeros( srcGray.size(), srcGray.type() );
	cv::Rect bRect = cv::Rect(0,0,0,0);
	for( int i = 0; i< contours.size(); i++ )
	{
		if (cv::contourArea(contours[i]) > 0.00001*src.rows*src.cols)
		{
			bRect = cv::boundingRect(contours[i]);
			cv::inRange(srcHsv(bRect), cv::Scalar(h_min,50,50), cv::Scalar(h_max,255,255), imgMap(bRect));
		}
	}
	cv::erode(imgMap, imgMap, getStructuringElement(cv::MORPH_ELLIPSE, cv::Size(1, 1)));
	cv::dilate(imgMap, imgMap, getStructuringElement(cv::MORPH_ELLIPSE, cv::Size(3, 3)));

	//Draw contours
	cv::Mat drawing = cv::Mat::zeros( cannyOutput.size(), CV_8UC3 );
	for( int i = 0; i< contours.size(); i++ )
	{
		cv::Scalar color = cv::Scalar( rng.uniform(0, 255), rng.uniform(0,255), rng.uniform(0,255) );
		drawContours( drawing, contours, i, cv::Scalar(0,0,255), 1, 8);
	}
	/*// Show in a window
	cv::namedWindow( "Contours", CV_WINDOW_AUTOSIZE );
	cv::imshow( "Contours", drawing );
	cv::namedWindow( "imgMap", CV_WINDOW_AUTOSIZE );
	cv::imshow( "imgMap", imgMap );*/
	
}
示例#6
0
void RenderConvexityDefects(CVPipeline * pipe)
{
	cv::Scalar color = cv::Scalar(rng.uniform(155,255), rng.uniform(125,255), rng.uniform(0,200));
	List<cv::Vec4i> defects = pipe->convexityDefects;
	for (int i = 0; i < defects.Size(); ++i)
	{
		cv::Vec4i defect = defects[i];
		int farthestPointIndex = defect[2];
		cv::Point farthestPoint = pipe->cvContours[0][farthestPointIndex];
		// Render point furthest away?
		cv::circle(pipe->output, farthestPoint, 3, color, 5);
	}
}
void CornerDetection::myShiTomasi_function(cv::Mat img, cv::Mat img_gray, cv::Mat myShiTomasi_dst)
{
	myShiTomasi_copy = img.clone();

	if( myShiTomasi_qualityLevel < 1 )
		myShiTomasi_qualityLevel = 1;

	for( int j = 0; j < img_gray.rows; j++ )
		for( int i = 0; i < img_gray.cols; i++ )
			if( myShiTomasi_dst.at<float>(j,i) > myShiTomasi_minVal + ( myShiTomasi_maxVal - myShiTomasi_minVal )*myShiTomasi_qualityLevel/max_qualityLevel )
				cv::circle( myShiTomasi_copy, cv::Point(i,j), 4, cv::Scalar( rng.uniform(0,255), rng.uniform(0,255), rng.uniform(0,255) ), -1, 8, 0 );
		
	cv::imshow( shiTomasi_win, myShiTomasi_copy );
}
示例#8
0
void DataProviderDTang<Dtype>::shuffle() {
  static cv::RNG rng(time(0));
                                  
  std::vector<boost::filesystem::path> shuffled_depth_paths(depth_paths_.size());
  std::vector<std::vector<cv::Vec3f> > shuffled_annos(annos_.size());
  
  for(size_t idx = 0; idx < depth_paths_.size(); ++idx) {
    int rand_idx = rng.uniform(0, depth_paths_.size());
    shuffled_depth_paths[idx] = depth_paths_[rand_idx];
    shuffled_annos[idx] = annos_[rand_idx];
  }
  
  depth_paths_ = shuffled_depth_paths;
  annos_ = shuffled_annos;
}
示例#9
0
void RenderContours(CVPipeline * pipe)
{
	/// Use same random seed every time to avoid rainbow hell..
	rng = cv::RNG(12345);
	for (int i = 0; i < pipe->contours.Size(); ++i)
	{			
		CVContour * contour = &pipe->contours[i];
		if (contour->segments.Size())
			RenderContourSegments(contour, pipe);
		else 
		{
			cv::Scalar color = cv::Scalar(rng.uniform(0,255), rng.uniform(0,255), rng.uniform(0,255));
			cv::drawContours(pipe->output, pipe->cvContours, i, color, 2, 8, pipe->contourHierarchy, 0, cv::Point());
		}
	}
}
示例#10
0
 double randomDoubleLog(double minVal, double maxVal)
 {
     double logMin = log((double)minVal + 1);
     double logMax = log((double)maxVal + 1);
     double pow = rng.uniform(logMin, logMax);
     double v = exp(pow) - 1;
     CV_Assert(v >= minVal && (v < maxVal || (v == minVal && v == maxVal)));
     return v;
 }
示例#11
0
void RenderConvexHulls(CVPipeline * pipe)
{
	if (pipe->cvContours.size() == 0)
		return;
	cv::Scalar color = cv::Scalar(rng.uniform(125,255), rng.uniform(125,255), rng.uniform(125,255));
//	cv::drawContours(pipe->output, pipe->convexHull, 0, color, 1, 8, std::vector<cv::Vec4i>(), 0, cv::Point() );
	std::vector<int> & convexHull = pipe->convexHull;
	std::vector<cv::Point> & contour = pipe->cvContours[0];
	for (int i = 0; i < convexHull.size(); ++i)
	{
		int index = convexHull[i];
		cv::Point point = contour[index];
		cv::circle(pipe->output, point, 15, color);
		int nextIndex = convexHull[(i+1) % convexHull.size()];
		cv::Point point2 = contour[nextIndex];
		// Line!
		cv::line(pipe->output, point, point2, color, 3);
	}
}
示例#12
0
Rectangle::Rectangle(const cv::Rect &_rect, const int &_id) :
    rect(_rect)
{
    tl = _rect.tl();
    br = _rect.br();
    left = new VerticalLine();
    left->set(tl, cv::Point(tl.x, br.y));
    top = new HorizontalLine();
    top->set(tl, cv::Point(br.x, tl.y));
    bottom = new HorizontalLine();
    bottom->set(cv::Point(tl.x, br.y), br);
    right = new VerticalLine();
    right->set(cv::Point(br.x, tl.y), br);
    info.set(_id, _rect);
    selected = false;
    selected_color = RED_COLOR;
    offset = 4;
    lineOffset = LINE_WEIGHT;
    color = cv::Scalar( rng.uniform(0, 255), rng.uniform(0,255), rng.uniform(0,255) );

}
示例#13
0
void drawEpipolar( cv::Mat _imga, cv::Mat _imgb,
                   std::vector<Eigen::VectorXi> _p2Da,
                   std::vector<Eigen::VectorXi> _p2Db,
                   std::vector<Eigen::VectorXd> _pda,
                   std::vector<Eigen::VectorXd> _pdb )
{

    char num[] = "12";

    for( unsigned int i = 0; i < _p2Da.size(); i++ )
    {
        Scalar color = Scalar( rng.uniform(0, 255), rng.uniform(0, 255), rng.uniform(0, 255) );
        sprintf( num, "%d ", i);

        circle( _imga, Point( _p2Da[i](0), _p2Da[i](1)), 5, color, -1, 8, 0 );
        putText( _imga, num, Point( _p2Da[i](0), _p2Da[i](1) ), FONT_HERSHEY_SIMPLEX, 1, color, 2, 8, false);

        sprintf( num, "%d ", i);
        circle( _imgb, Point( _p2Db[i](0), _p2Db[i](1)), 5, color, -1, 8, 0 );
        putText( _imgb, num, Point( _p2Db[i](0), _p2Db[i](1) ), FONT_HERSHEY_SIMPLEX, 1, color, 2, 8, false);

        Point2f pt1a;
        Point2f pt2a;
        pt1a.x = _pda[i](0);
        pt1a.y = _pda[i](1);
        pt2a.x = _pda[i](2);
        pt2a.y = _pda[i](3);

        line( _imga, pt1a, pt2a, color, 2, CV_AA );

        Point2f pt1b;
        Point2f pt2b;
        pt1b.x = _pdb[i](0);
        pt1b.y = _pdb[i](1);
        pt2b.x = _pdb[i](2);
        pt2b.y = _pdb[i](3);

        line( _imgb, pt1b, pt2b, color, 2, CV_AA );
    }
}
示例#14
0
void CropIm(std::string destFoldPath, cv::Mat Im, double s)
{
	int w = Im.rows;
	int h = Im.cols;

	int wStart;
	int hStart;
	
	wStart = rng.uniform(0.0, w*(1-s));
	hStart = rng.uniform(0.0, h*(1-s));

	cv::Rect myROI(hStart, wStart, h*s, w*s);

	cv::Mat croppedImage = Im(myROI);
	cv::imwrite(destFoldPath + "_crop" + int2string(int(s * 100)) + ".jpg", croppedImage);
}
示例#15
0
void
gen_points_3d(std::vector<Plane>& planes_out, cv::Mat_<unsigned char> &plane_mask, cv::Mat& points3d, cv::Mat& normals,
              int n_planes)
{
    std::vector<Plane> planes;
    for (int i = 0; i < n_planes; i++)
    {
        Plane px;
        for (int j = 0; j < 1; j++)
        {
            px.set_d(rng.uniform(-3.f, -0.5f));
            planes.push_back(px);
        }
    }
    cv::Mat_ < cv::Vec3f > outp(H, W);
    cv::Mat_ < cv::Vec3f > outn(H, W);
    plane_mask.create(H, W);

    // n  ( r - r_0) = 0
    // n * r_0 = d
    //
    // r_0 = (0,0,0)
    // r[0]
    for (int v = 0; v < H; v++)
    {
        for (int u = 0; u < W; u++)
        {
            unsigned int plane_index = (u / float(W)) * planes.size();
            Plane plane = planes[plane_index];
            outp(v, u) = plane.intersection(u, v, Kinv);
            outn(v, u) = plane.n;
            plane_mask(v, u) = plane_index;
        }
    }
    planes_out = planes;
    points3d = outp;
    normals = outn;
}
cv::Mat PerspectiveTransform::warpPerspectiveRand( cv::RNG& rng )
{
    cv::Mat H;
    
    H.create(3, 3, CV_64FC1);
    H.at<double>(0,0) = rng.uniform( 0.8f, 1.2f);
    H.at<double>(0,1) = rng.uniform(-0.1f, 0.1f);
    //H.at<double>(0,2) = rng.uniform(-0.1f, 0.1f)*src.cols;
    H.at<double>(0,2) = rng.uniform(-0.1f, 0.1f);
    H.at<double>(1,0) = rng.uniform(-0.1f, 0.1f);
    H.at<double>(1,1) = rng.uniform( 0.8f, 1.2f);
    //H.at<double>(1,2) = rng.uniform(-0.1f, 0.1f)*src.rows;
    H.at<double>(1,2) = rng.uniform(-0.1f, 0.1f);
    H.at<double>(2,0) = rng.uniform( -1e-4f, 1e-4f);
    H.at<double>(2,1) = rng.uniform( -1e-4f, 1e-4f);
    H.at<double>(2,2) = rng.uniform( 0.8f, 1.2f);

    return H;
}
示例#17
0
文件: thresCat.cpp 项目: jebr224/cat
void thresh_callback(int, void* )
{
  cv::Mat canny_output;
  std::vector<std::vector<cv::Point> > contours;
  std::vector<cv::Vec4i> hierarchy;

  /// Detect edges using canny
   cv::threshold( blur, canny_output, thresh, 255 ,1 );

  cv::namedWindow("canny",CV_WINDOW_NORMAL);
  cv::imshow("canny",canny_output);
  /// Find contours
  cv::findContours( canny_output, contours, hierarchy, cv::RETR_TREE, cv::CHAIN_APPROX_SIMPLE, cv::Point(0, 0) );

  for( int f =0; f <listOfMarks.size();f++)
  {
       delete listOfMarks[f];
  }
  listOfMarks.clear();

  /// Draw contours
  cv::Mat drawing = cv::Mat::zeros( canny_output.size(), CV_8UC3 );
  for( size_t i = 0; i< contours.size(); i++ )
  {
       cv::Scalar color = cv::Scalar( rng.uniform(0, 255), rng.uniform(0,255), rng.uniform(0,255) );
       cv::drawContours( drawing, contours, (int)i, cv::Scalar(255,255,255), thick, 8, hierarchy, 0, cv::Point() );
//       mark *temp = new mark(contours[i]);
//       listOfMarks.push_back(temp);

  } 


  /// Show in a window
  cv::namedWindow( "Contours", CV_WINDOW_NORMAL );
  cv::imshow( "Contours", drawing );
//-------------------------------------------again

    
  std::vector<std::vector<cv::Point> > contours_again;
  std::vector<cv::Vec4i> hierarchy_again;

  draw_again = cv::Mat::zeros(   canny_output.size(), CV_8UC3 );

  colorOutImage = cv::Mat::zeros(canny_output.size(), CV_8UC3);

  cv::Mat temp;
  cv::cvtColor(  drawing,temp, cv::COLOR_BGR2GRAY );
  cv::findContours(  temp , contours_again, hierarchy_again, cv::RETR_TREE, cv::CHAIN_APPROX_SIMPLE, cv::Point(0, 0) );
  

  for( size_t i = 0; i< contours_again.size(); i++ )
  {
//       cv::Scalar color = cv::Scalar( rng.uniform(0, 255), rng.uniform(0,255), rng.uniform(0,255) );
       cv::Scalar color = cv::Scalar(255,255,255);
       cv::drawContours( draw_again, contours_again, (int)i, color , 2, 8, hierarchy, 0, cv::Point() );
       mark * temp = new mark(contours_again[i]);
       listOfMarks.push_back(temp);
  }

  /// Show in a window
//  cv::namedWindow( "Contours_again", CV_WINDOW_NORMAL );
//  cv::imshow( "Contours_again", draw_again );



  for(int h = 0; h < listOfMarks.size();h++)
  {
     

     int y  = (listOfMarks[h]->high_y() + listOfMarks[h]->low_y()) / 2;
     int x1 = listOfMarks[h]->high_x() + length;
     int x2 = listOfMarks[h]->low_x() - length;
     cv::Point one = cv::Point(x1,y);
     cv::Point two = cv::Point(x2,y);     
     cv::Scalar white =cv::Scalar(255,255,255); 

     cv::line(draw_again, one, two, white, thick,8,0);

  }

  cv::namedWindow( "Contours_again", CV_WINDOW_NORMAL );
  cv::imshow( "Contours_again", draw_again );

   
  std::vector< std::vector<cv::Point> > contour_3;
  std::vector<cv::Vec4i> hierarchy_3;
  cv::Mat temp_3;
  cv::cvtColor(  draw_again,temp_3, cv::COLOR_BGR2GRAY );
  std::cerr<<"cvtColo" <<std::endl;  
  cv::findContours(  temp_3, contour_3, hierarchy_3, cv::RETR_TREE, cv::CHAIN_APPROX_SIMPLE, cv::Point(0, 0) ); 
  std::cerr<<"found contours" << std::endl;
  for( size_t i = 0; i< contour_3.size(); i++ )
  {
       cv::Scalar color = cv::Scalar( rng.uniform(0, 255), rng.uniform(0,255), rng.uniform(0,255) );
//       cv::Scalar color = cv::Scalar(255,255,255);
       cv::drawContours( colorOutImage, contour_3, (int)i, color , 2, 8, hierarchy_3, 0, cv::Point() );
  }
  std::cerr<<"drawContours"<<std::endl;  
  
  cv::namedWindow( "Contours_3", CV_WINDOW_NORMAL );
  cv::imshow( "Contours_3", colorOutImage );

  std::cout<<std::endl<<"number of contours -> " <<contours.size();
 
//again--------------------------------------------------------------------------


  


//  makeZones_callback(0,0);
}
示例#18
0
    void getDistortionValues(cv::RNG &rng, const Size2i &inputSize, AugParams *agp) {
        // This function just gets the random distortion values without modifying the
        // image itself.  Useful if we need to reapply the same transformations over
        // again (e.g. for all frames of a video or for a corresponding target mask)

        // colornoise values
        // N.B. if _contrastMax == 100, then _colorNoiseStd will be 0.0
        for (int i=0; i<3; i++) {
            agp->colornoise[i] = rng.gaussian(_colorNoiseStd);
        }

        // contrast, brightness, saturation
        // N.B. all value ranges tied to _contrastMin and _contrastMax
        for (int i=0; i<3; i++) {
            agp->cbs[i] = rng.uniform(_contrastMin, _contrastMax) / 100.0f;
        }

        /**************************
        *  HORIZONTAL FLIP        *
        ***************************/
        agp->flip = _flip && rng(2) != 0  ? true : false;

        /**************************
        *  ROTATION ANGLE         *
        ***************************/
        agp->angle = rng.uniform(_rotateMin, _rotateMax);

        /**************************
        *  CROP BOX               *
        ***************************/
        float shortSide = std::min(inputSize.height, inputSize.width);

        // Special case where we just grab the whole image;
        if (_scaleMin == 0) {
            agp->cropBox = Rect(Point2i(), inputSize);
            return;
        }

        if (_center) {
            agp->cropBox.width = shortSide * _width / (float) _scaleMin;
            agp->cropBox.height = shortSide * _height / (float) _scaleMin;
            agp->cropBox.x = (inputSize.width - agp->cropBox.width) / 2;
            agp->cropBox.y = (inputSize.height - agp->cropBox.height) / 2;
        } else {
            cv::Size2f oSize = inputSize;

            // This is a hack for backward compatibility.
            // Valid aspect ratio range ( > 100) will override side scaling behavior
            if (_aspectRatio == 0) {
                float scaleFactor = rng.uniform(_scaleMin, _scaleMax);
                agp->cropBox.width = shortSide * _width / scaleFactor;
                agp->cropBox.height = shortSide * _height / scaleFactor;
            } else {
                float mAR = (float) _aspectRatio / 100.0f;
                float nAR = rng.uniform(1.0f / mAR, mAR);
                float oAR = oSize.width / oSize.height;
                // between minscale pct% to 100% subject to aspect ratio limitation
                float maxScale = nAR > oAR ? oAR / nAR : nAR / oAR;
                float minScale = std::min((float) _scaleMin / 100.0f, maxScale);
                float tgtArea = rng.uniform(minScale, maxScale) * oSize.area();

                agp->cropBox.height = sqrt(tgtArea / nAR);
                agp->cropBox.width = agp->cropBox.height * nAR;
            }

            agp->cropBox.x = rng.uniform(0, inputSize.width - agp->cropBox.width);
            agp->cropBox.y = rng.uniform(0, inputSize.height - agp->cropBox.height);

        }
        return;
    }
示例#19
0
文件: locateLP.cpp 项目: kothemel/LPR
int main( int argc, char** argv ) {
	/// Load an image
	cv::Mat src, greyIm, histeqIm;

	src = cv::imread( argv[1] );

	if( !src.data ) {
		printf("Input file? No? ouuuupsss thooooorryyyyy\n");
		return -1;
	}


	cv::Size s = src.size();
	int rows = s.height;
	int cols = s.width;
	// Setup a rectangle to define your region of interest
	cv::Rect myROI(0, rows/2, cols, rows/2);

	// Crop the full image to that image contained by the rectangle myROI
	// Note that this doesn't copy the data
	cv::Mat croppedImage = src(myROI);

	cv::imwrite("output/1_low_half.jpg", croppedImage);

	cv::cvtColor(croppedImage, greyIm, cv::COLOR_BGR2GRAY);

    cv::Size crop_size = croppedImage.size();
    int crop_rows = crop_size.height;
    int crop_cols = crop_size.width;


	cv::imwrite("output/2_grey_scale.jpg", greyIm);

	cv::equalizeHist( greyIm, histeqIm );

	cv::imwrite("output/3_hist_eq.jpg", histeqIm);	




	std::vector<std::vector<cv::Point> > contours;
    std::vector<cv::Vec4i> hierarchy;

    // Reduce noise with kernel 3x3
    cv::Mat blurIm;
    blur(histeqIm, blurIm, cv::Size(3,3));

	cv::imwrite("output/4_blur.jpg", blurIm);

    // Canny detector
    cv::Mat edgesIm;
    Canny(blurIm, edgesIm, thresh, thresh*ratio, kernel_size);

    cv::imwrite("output/5_edge.jpg", edgesIm);
    
    // Find contours
    cv::findContours(edgesIm, contours, hierarchy, cv::RETR_TREE, cv::CHAIN_APPROX_SIMPLE, cv::Point(0,0));

    // Approximate contours to polygons + get bounding rects and circles
    std::vector<std::vector<cv::Point> > contours_poly(contours.size());
    std::vector<cv::Rect> boundRect(contours.size());
    std::vector<cv::Point2f>center(contours.size());
    std::vector<float>radius(contours.size());

    for (int i = 0; i < contours.size(); i++) {
        cv::approxPolyDP(cv::Mat(contours[i]), contours_poly[i], 3, true);
        boundRect[i] = cv::boundingRect(cv::Mat(contours_poly[i]));
        cv::minEnclosingCircle((cv::Mat)contours_poly[i], center[i], radius[i]);
    }

    // Draw contours
    int j=0;
    cv::Mat drawing = cv::Mat::zeros(edgesIm.size(), CV_8UC3);
    cv::Mat piece[5], hsvIm[5];
    for (int i = 0; i < contours.size(); i++) {
        if (!((boundRect[i].height >= boundRect[i].width/5) && (boundRect[i].height <= boundRect[i].width/2) 
            && boundRect[i].height<=crop_rows/4 && boundRect[i].width<=crop_cols/2   
            && boundRect[i].height>=crop_rows/10 && boundRect[i].width>=crop_cols/6)) 
        continue;

        cv::Rect roi = boundRect[i];
        piece[j] = croppedImage(roi);
        imwrite("output/contour"+std::to_string(j)+".jpg", piece[j]);
        j++;

        cv::Scalar color = cv::Scalar(rng.uniform(0, 255), rng.uniform(0,255), rng.uniform(0,255));
        cv::drawContours(drawing, contours, i, color, 2, 8, hierarchy, 0, cv::Point());
        cv::rectangle(drawing, boundRect[i].tl(), boundRect[i].br(), color, 2, 8, 0);
        //circle(drawing, center[i], (int)radius[i], color, 2, 8, 0);  
    }

    imwrite("output/6_contours.jpg", drawing);



    int h_bins = 50; int s_bins = 60;
    int histSize[] = { h_bins, s_bins };

    float h_ranges[] = { 0, 180 };
    float s_ranges[] = { 0, 256 };

    const float* ranges[] = { h_ranges, s_ranges };

    int channels[] = { 0, 1 };

    cv::Mat hist[5];

    for (int i=0; i<j; i++){
        cvtColor(piece[i], hsvIm[i], cv::COLOR_BGR2HSV);
        imwrite("output/hsvIm"+std::to_string(i)+".jpg", hsvIm[i]);

        calcHist( &hsvIm[i], 1, channels, cv::Mat(), hist[i], 2, histSize, ranges, true, false );
        //normalize( hsvIm[i], hsvIm[i], 0, 1, cv::NORM_MINMAX, -1, cv::Mat() );
    }












	return 0;
}
示例#20
0
void CVDataFilter::Paint(CVPipeline * pipe)
{
	if (returnType == CVReturnType::QUADS)
	{
		// Draw quads.
		if (!pipe->quads.Size())
			return;
		// Copy original input
		pipe->initialInput.copyTo(pipe->output);
		// Convert to color if needed.
		int channelsBefore = pipe->output.channels();
		if (channelsBefore == 1)
		{
		//	pipe->output.convertTo(pipe->output, CV_8UC3);
			cv::cvtColor(pipe->output, pipe->output, CV_GRAY2RGB);
		}
		int channelsAfter = pipe->output.channels();
		// o.o Paste!
		for (int i = 0; i < pipe->quads.Size(); ++i)
		{
			Quad quad = pipe->quads[i];
	#define RGB(r,g,b) cv::Scalar(b,g,r)
			rng = cv::RNG(1344);
			cv::Scalar color = RGB(rng.uniform(0, 255),rng.uniform(0, 255),rng.uniform(0, 255));
		//	cv::Mat rectImage = cv::Mat::zeros(pipe->output.size(), CV_8UC3);
			cv::rectangle(pipe->output, cv::Point(quad.point1.x, quad.point1.y), cv::Point(quad.point3.x, quad.point3.y), color, CV_FILLED);
			float alpha = 0.2f;
			float beta = 1 - alpha;
		//	cv::addWeighted(rectImage, alpha, pipe->output, beta, 0.0, pipe->output); 
		//	rectImage.copyTo(pipe->output);		
		}
	}
	else if (returnType == CVReturnType::APPROXIMATED_POLYGONS)
	{
		// Copy original input..
		pipe->initialInput.copyTo(pipe->output);
		RenderPolygons(pipe);
	}
	else if (returnType == CVReturnType::CV_IMAGE)
	{
		// Do nothing as the image should already be in the ouput matrix of the pipeline.
	}
	else if (returnType == CVReturnType::LINES ||
		returnType == CVReturnType::CV_LINES)
	{
		// Convert the color to colors again for visualization...
		pipe->initialInput.copyTo(pipe->output);
		for( size_t i = 0; i < pipe->lines.Size(); i++ )
		{
			Line & line = pipe->lines[i];
			// Multiply the line coordinates with the last used inverted scale.
			line.start *= pipe->currentScaleInv;
			line.stop *= pipe->currentScaleInv;

			cv::line( pipe->output, cv::Point(line.start.x, line.start.y),
				cv::Point(line.stop.x, line.stop.y), cv::Scalar(0,0,255), 3, 8 );
		}
	}
	else if (returnType == CVReturnType::CV_CONTOURS)
	{
		pipe->initialInput.copyTo(pipe->output);
		RenderContours(pipe);
	}

	switch(returnType)
	{
		case CVReturnType::CV_CONTOUR_SEGMENTS:
		{
			// Render shit!
			pipe->initialInput.copyTo(pipe->output);
			RenderContourSegments(pipe);
			break;
		}
	}

	if (returnType == CVReturnType::CV_CONTOUR_ELLIPSES)
	{
		pipe->initialInput.copyTo(pipe->output);
		RenderContours(pipe);
		RenderContourBounds(pipe);
	}
	else if (returnType == CVReturnType::CV_CONVEX_HULLS)
	{
		pipe->initialInput.copyTo(pipe->output);
		RenderContours(pipe);
		RenderConvexHulls(pipe);
	}
	else if (returnType == CVReturnType::CV_CONVEXITY_DEFECTS)
	{
		pipe->initialInput.copyTo(pipe->output);
		RenderContours(pipe);
		RenderConvexHulls(pipe);
		RenderConvexityDefects(pipe);
	}
	else if (returnType == CVReturnType::HANDS)
	{
		// Convert image to RGB for easier display
		int channelsBefore = pipe->initialInput.channels();
	//	cv::cvtColor(*pipe->initialInput, pipe->output, CV_GRAY2RGB);
		pipe->initialInput.copyTo(pipe->output);
		int channelsAfter = pipe->output.channels();
		// Check if we got contour-segments, if so prioritize them.
		RenderHands(pipe);
	}
	else if (returnType == CVReturnType::FINGER_STATES)
	{
		// Render the last known one.
		pipe->initialInput.copyTo(pipe->output);
		FingerState & state = pipe->fingerStates.Last();
		cv::Scalar color(255,0,0,255);
		for (int i = 0; i < state.positions.Size(); ++i)
		{
			Vector3f pos = state.positions[i];
			cv::circle(pipe->output, cv::Point(pos.x, pos.y), 5, color, 3);
		}
	}
	else if (returnType == CVReturnType::POINT_CLOUDS)
	{
		pipe->initialInput.copyTo(pipe->output);
		for (int i = 0; i < pipe->pointClouds.Size(); ++i)
		{
			int r,g,b,a;
			r = g = b = a = 255;
			if (i % 2 == 0)
				g = 0;
			if (i % 4 == 0)
				b = 0;
			cv::Scalar color(r,g,b,a);
			
			CVPointCloud & pc = pipe->pointClouds[i];
			for (int j = 0; j < pc.points.Size(); ++j)
			{
				Vector2f & pos = pc.points[j];
				cv::circle(pipe->output, cv::Point(pos.x, pos.y), 2, color, 3);
			}

			/// Render PCA data if applicable.
			for (int j = 0; j < pc.eigenVectors.Size(); ++j)
			{
				cv::Scalar color = j == 0? CV_RGB(255, 255, 0) : CV_RGB(0, 255, 255);
				cv::Point2f eigenVector(pc.eigenVectors[j].x, pc.eigenVectors[j].y);
				float eigenValue = pc.eigenValues[j];

				cv::Point2f scaledEigenVector = eigenVector * eigenValue * 0.02;

				cv::Point2f pcaCenter(pc.pcaCenter.x, pc.pcaCenter.y);
				circle(pipe->output, pcaCenter, 3, CV_RGB(255, 0, 255), 2);
				line(pipe->output, pcaCenter, pcaCenter + scaledEigenVector, color);
			}
		}
	}
	else if (returnType == CVReturnType::CV_OPTICAL_FLOW)
	{
		// http://stackoverflow.com/questions/7693561/opencv-displaying-a-2-channel-image-optical-flow
		// Split the coordinates.
		/*
		cv::Mat xy[2];
		cv::split(pipe->opticalFlow, xy);

		cv::Mat magnitude, angle;

		// Fetch matrix from pipeline.
		cv::cartToPolar(xy[0], xy[1], magnitude, angle, true);

		double magMax;
		cv::minMaxLoc(magnitude, 0, &magMax);
		magnitude.convertTo(magnitude, -1, 1.0 / magMax);
		
		// Build HSV image?
		cv::Mat hsvChannels[3], hsv;
		hsvChannels[0] = angle;
		hsvChannels[1] = cv::Mat::ones(angle.size(), CV_32F);
		hsvChannels[2] = magnitude;
		cv::merge(hsvChannels, 3, hsv);

		// Convert to rgb and send to output.
		cv::cvtColor(hsv, pipe->output, cv::COLOR_HSV2RGB);
		*/
	}
	else if (returnType == CVReturnType::NOTHING)
	{
		// Nothing to render...
	}
	else if (returnType == -1)
	{
		// Nothing to render if error.
		std::cout<<"\nreturnType variable in filter "<<name<<" not set!";
	}
	else if (returnType == CVReturnType::RENDER)
		// Nothing to render if render.
		;
	else
		; // std::cout<<"\nCVDataFilter::Paint called. Forgot to subclass the paint-method?";
}
JNIEXPORT void JNICALL
Java_ph_edu_dlsu_circles_CameraActivity_process(JNIEnv *env, jobject instance,
                                                            jobject pTarget, jbyteArray pSource, jint thresh) {
    uint32_t t;
    cv::Mat srcBGR;
    cv::Mat edges;

    cv::Scalar color;

    std::vector<cv::Vec3f> circles;

    AndroidBitmapInfo bitmapInfo;
    uint32_t* bitmapContent;

    if(AndroidBitmap_getInfo(env, pTarget, &bitmapInfo) < 0) abort();
    if(bitmapInfo.format != ANDROID_BITMAP_FORMAT_RGBA_8888) abort();
    if(AndroidBitmap_lockPixels(env, pTarget, (void**)&bitmapContent) < 0) abort();

    /// Access source array data... OK
    jbyte* source = (jbyte*)env->GetPrimitiveArrayCritical(pSource, 0);
    if (source == NULL) abort();

    /// cv::Mat for YUV420sp source and output BGRA
    cv::Mat srcGray(bitmapInfo.height, bitmapInfo.width, CV_8UC1, (unsigned char *)source);
    cv::Mat src(bitmapInfo.height + bitmapInfo.height/2, bitmapInfo.width, CV_8UC1, (unsigned char *)source);
    cv::Mat mbgra(bitmapInfo.height, bitmapInfo.width, CV_8UC4, (unsigned char *)bitmapContent);


/***********************************************************************************************/
    /// Native Image Processing HERE...

    t = cv::getTickCount();

    if(srcBGR.empty())
        srcBGR = cv::Mat(bitmapInfo.height, bitmapInfo.width, CV_8UC3);

    cv::cvtColor(src, srcBGR, CV_YUV420sp2RGB);

    // Reduce noise
    cv::GaussianBlur( srcGray, srcGray, cv::Size(9, 9), 2, 2 );

    // Detect the circles
    cv::HoughCircles(srcGray, circles, CV_HOUGH_GRADIENT, 1, srcGray.rows/4, 200, thresh > 0 ? thresh : 1, 5);

    // Draw the circles

    for(size_t i = 0; i < circles.size(); i++) {

        cv::Point center(cvRound(circles[i][0]), cvRound(circles[i][1]));

        int radius = cvRound(circles[i][2]);

        color = cv::Scalar( rng.uniform(0, 255), rng.uniform(0,255), rng.uniform(0,255) );

        // draw the circle center
        cv::circle(srcBGR, center, 3, color, -1, 8, 0);

        // draw the circle outline
        cv::circle(srcBGR, center, radius, color, 3, 8, 0);
    }


    LOGI("Processing took %0.2f ms.", 1000*((float)cv::getTickCount() - t)/(float)cv::getTickFrequency());

    cvtColor(srcBGR, mbgra, CV_BGR2BGRA);


/************************************************************************************************/

    /// Release Java byte buffer and unlock backing bitmap
    //env-> ReleasePrimitiveArrayCritical(pSource,source,0);
    /*
     * If 0, then JNI should copy the modified array back into the initial Java
     * array and tell JNI to release its temporary memory buffer.
     *
     * */

    env-> ReleasePrimitiveArrayCritical(pSource, source, JNI_COMMIT);
    /*
 * If JNI_COMMIT, then JNI should copy the modified array back into the
 * initial array but without releasing the memory. That way, the client code
 * can transmit the result back to Java while still pursuing its work on the
 * memory buffer
 *
 * */

    /*
     * Get<Primitive>ArrayCritical() and Release<Primitive>ArrayCritical()
     * are similar to Get<Primitive>ArrayElements() and Release<Primitive>ArrayElements()
     * but are only available to provide a direct access to the target array
     * (instead of a copy). In exchange, the caller must not perform blocking
     * or JNI calls and should not hold the array for a long time
     *
     */


    if (AndroidBitmap_unlockPixels(env, pTarget) < 0) abort();
}
示例#22
0
int main_center_of_mass(int argc, char* argv[]){
	char* file = "contours.png";

	int thresh = 100;

	//src.convertTo(src_gray,CV_8U);

	while(true){
		cv::Mat src = cv::imread(file);
	cv::Mat src_gray;// = cv::imread(file,0);
	cv::cvtColor(src,src_gray,CV_RGB2GRAY);
		cv::dilate( src_gray, src_gray, cv::Mat() );
		cv::erode( src_gray, src_gray, cv::Mat() );
	//cv::threshold(src,src_gray,0.5,255,CV_THRESH_BINARY);

	cv::Mat1b src_g;
	cv::cvtColor(src,src_g,CV_RGB2GRAY);

	cv::Mat canny_output;
	cv::vector<cv::vector<cv::Point> > contours;
	cv::vector<cv::Vec4i> hierarchy;

	/// Detect edges using canny
	cv::Canny( src_gray, canny_output, thresh, thresh*2, 3 );

	cv::imshow("canny",canny_output);

	/// Find contours
	cv::findContours( canny_output, contours, hierarchy, CV_RETR_LIST, CV_CHAIN_APPROX_SIMPLE, cv::Point(0, 0) );
	
	cv::Mat drawing = cv::Mat::zeros( canny_output.size(), CV_8UC3 );	
	
	int idx = 0;
	int max = -1;
	for(unsigned int i = 0; i< contours.size(); i++ ){
		cv::Scalar color3 = cv::Scalar( rng.uniform(0, 255), rng.uniform(0,255), rng.uniform(0,255) );
		drawContours( drawing, contours, i, color3, 2, 8, hierarchy, 0, cv::Point() );
		int coiso = contours.at(i).size();
		if(coiso > max){
			idx = i;
			max = coiso;
		}
	}

	cv::Moments mm = moments( contours[idx], false );
	cv::Point2f center = cv::Point2f((float)(mm.m10/mm.m00) , (float)(mm.m01/mm.m00));
	cv::Rect rect = cv::boundingRect(cv::Mat(contours[idx]));


	
	for(unsigned int i = rect.y ; i < rect.y + rect.height; i++){
		
		for(unsigned int j = rect.x ; j < rect.x + rect.width  ; j++){
			cv::Scalar color2 = cv::Scalar( rng.uniform(0, 255), rng.uniform(0,255), rng.uniform(0,255) );
			
			if(src_gray.ptr<unsigned char>(i)[j]){
				drawing.ptr<unsigned char>(i)[3*j]	= (unsigned char)color2.val[0]; // first channel
				drawing.ptr<unsigned char>(i)[3*j+1]= (unsigned char)color2.val[1]; // second channel
				drawing.ptr<unsigned char>(i)[3*j+2]= (unsigned char)color2.val[2]; // third channel
				//cv::circle( drawing, pt, 1, color2, -1, 2, 0 );
			}
		}
	}

	cv::Scalar color = cv::Scalar( 255, 255, 255 );
	drawContours( drawing, contours, idx, color, 2, 8, hierarchy, 0, cv::Point() );
	cv::circle( drawing, center, 4, color, -1, 8, 0 );
	cv::rectangle(src,rect,color);

/*	/// Get the moments
	cv::vector<cv::Moments> mu(contours.size() );
	for( int i = 0; i < contours.size(); i++ )
		{ mu[i] = moments( contours[i], false ); }

	///  Get the mass centers:
	cv::vector<cv::Point2f> mc( contours.size() );
	for( int i = 0; i < contours.size(); i++ )
		{ mc[i] = cv::Point2f( mu[i].m10/mu[i].m00 , mu[i].m01/mu[i].m00 ); }
	

	cv::Mat drawing = cv::Mat::zeros( canny_output.size(), CV_8UC3 );

	

		cv::Scalar color = cv::Scalar( rng.uniform(0, 255), rng.uniform(0,255), rng.uniform(0,255) );
		drawContours( drawing, contours, idx, color, 2, 8, hierarchy, 0, cv::Point() );
		cv::circle( src, mc[idx], 4, color, -1, 8, 0 );*/
	

	
	cv::imshow("src2",src);
	cv::imshow("cont",drawing);

	cv::waitKey(22);
	}

	return 0;
}
示例#23
0
PERF_TEST_P(Size_Dp_MinDist, OCL_HoughCircles,
            testing::Combine(
                testing::Values(perf::sz720p, perf::szSXGA, perf::sz1080p),
                testing::Values(1.0f, 2.0f, 4.0f),
                testing::Values(1.0f, 10.0f)))
{
    const cv::Size size = std::tr1::get<0>(GetParam());
    const float dp      = std::tr1::get<1>(GetParam());
    const float minDist = std::tr1::get<2>(GetParam());

    const int minRadius = 10;
    const int maxRadius = 30;
    const int cannyThreshold = 100;
    const int votesThreshold = 15;

    cv::RNG rng(123456789);

    cv::Mat src(size, CV_8UC1, cv::Scalar::all(0));

    const int numCircles = rng.uniform(50, 100);
    for (int i = 0; i < numCircles; ++i)
    {
        cv::Point center(rng.uniform(0, src.cols), rng.uniform(0, src.rows));
        const int radius = rng.uniform(minRadius, maxRadius + 1);

        cv::circle(src, center, radius, cv::Scalar::all(255), -1);
    }

    cv::ocl::oclMat ocl_src(src);
    cv::ocl::oclMat ocl_circles;
示例#24
0
 Mat randomMat(Size size, int type, double minVal, double maxVal, bool useRoi = false)
 {
     RNG dataRng(rng.next());
     return cvtest::randomMat(dataRng, size, type, minVal, maxVal, useRoi);
 }
示例#25
0
void Controller::generate_model(){
	//Create Average images;
	//this->_model_depth_average = cv::Mat::zeros(cv::Size(640,480),CV_16UC1);
	//this->_model_color_average = cv::Mat::zeros(cv::Size(640,480),CV_8UC3);
	//cv::Mat average_counter = cv::Mat::zeros(cv::Size(640,480),CV_8UC1);
	int old_step = this->_property_manager->_3d_step;

	cv::Mat1i freq_n(cv::Size(640,480),0);
	cv::Mat1f freq_v(cv::Size(640,480),0);
	cv::Mat freq_c = cv::Mat::zeros(cv::Size(640,480),CV_32FC3);

	int idx, idx_clr;
	float* ptr_freq_v = (float*)freq_v.data;
	int* ptr_freq_n = (int*)freq_n.data;
	float* ptr_freq_c = (float*)freq_c.data;

	//Create Depth and Color Sum Image
	for(int k = 0 ; k < this->_model_frames_depth.size() ; ++k){
		UINT16* ptr_16u = (UINT16*)this->_model_frames_depth[k].data;
		uint8_t* ptr_clr = (uint8_t*)this->_model_frames_color[k].data;
		for(int y = 0; y < XN_VGA_Y_RES ; ++y) { 
			for(int x = 0; x < XN_VGA_X_RES ; ++x) { 
				idx = y * XN_VGA_X_RES + x;
				if(ptr_16u[idx]){
					ptr_freq_n[idx]++;
					ptr_freq_v[idx]+=ptr_16u[idx];
				}

				idx_clr = y * XN_VGA_X_RES * 3 + x* 3;

				ptr_freq_c[idx_clr + 0] += ptr_clr[idx_clr + 0];
				ptr_freq_c[idx_clr + 1] += ptr_clr[idx_clr + 1];
				ptr_freq_c[idx_clr + 2] += ptr_clr[idx_clr + 2];
			} 
		}
	}

	//Create Depth and Color Average Image
	for(int y = 0; y < XN_VGA_Y_RES ; ++y) { 
		for(int x = 0; x < XN_VGA_X_RES ; ++x) {
			idx = y * XN_VGA_X_RES + x;
			if(ptr_freq_n[idx]){
				ptr_freq_v[idx] /= ptr_freq_n[idx];
			}
		}
	}

	freq_c /= this->_model_frames_color.size();
	
	
	freq_c.convertTo(this->_model_color_average,CV_8UC3);
	freq_v.convertTo(this->_model_depth_average,CV_16UC1);


	//cv::Mat t8u;
	//this->_model_depth_average.convertTo(t8u,CV_8UC1,0.05);
	//cv::imshow("win1",this->_model_color_average);
	////cv::imshow("win2",this->_mat_color_bgr);
	//cv::imshow("win3",t8u);
	//cv::imshow("win4",this->_mat_depth8UC1);
	//cv::waitKey();
	
	//Create Masks for avg images
	cv::Mat main_mask;

	cv::inRange(this->_model_depth_average,
				this->_property_manager->_depth_min,
				this->_property_manager->_depth_max,
				main_mask);

	cv::bitwise_and(main_mask,this->_mask_mirrors_and_foor,main_mask);


	//Contours to remove noise
	cv::Mat t8u;
	main_mask.convertTo(t8u,CV_8UC1,0.05);
	//cv::Mat image_temp;
	//this->_model_depth_average.copyTo(image_temp);

	cv::vector<cv::vector<cv::Point> > contours;
	cv::vector<cv::Vec4i> hierarchy;
			
	cv::findContours( t8u, contours, hierarchy, CV_RETR_EXTERNAL, CV_CHAIN_APPROX_SIMPLE, cv::Point(0, 0) );

	for(unsigned int i = 0; i< contours.size(); i++ ){
		if(contours[i].size() < 50){
			cv::Scalar clr = cv::Scalar(/*255);// */rng.uniform(0, 255), rng.uniform(0,255), rng.uniform(0,255) );
			cv::Rect rect = cv::boundingRect(contours[i]);
			drawContours( this->_model_color_average, contours, i, clr, -1, 8, hierarchy, 0, cv::Point() );
			//cv::rectangle(top_view_color,rect, clr);
		}
	}

	Mirror* mirror;
	uchar* ptr_mirror_mask = this->_mask_mirrors.data;

	//Generate 3D
	this->_model_n_points;

	uchar* ptr_main_mask = main_mask.data;
	//uchar* ptr_mirror_mask = this->_mask_mirrors.data;

	UINT16* ptr_16u = (UINT16*)this->_model_depth_average.data;

	for(int y = 0; y < XN_VGA_Y_RES ; ++y /*y += this->_property_manager->_3d_step*/) { 
		for(int x = 0; x < XN_VGA_X_RES ; ++x/*x += this->_property_manager->_3d_step*/) { 
			idx = y * XN_VGA_X_RES + x;

			if(ptr_main_mask[idx]){
				XnPoint3D point1;
				point1.X = x; 
				point1.Y = y; 
				point1.Z = ptr_16u[idx];

				if(ptr_mirror_mask[idx]){
					for(int j = 0 ; j < this->_mirrors.size() ; ++j){
						mirror = this->_mirrors[j];

						if(mirror && mirror->_area_mask.data[idx]){
							if(point1.Z > mirror->_depth_min && point1.Z < mirror->_depth_max){
								this->_model_back_3d_to_2d[this->_model_n_points][XX] = x;
								this->_model_back_3d_to_2d[this->_model_n_points][YY] = y;
				
								this->_model_projective[this->_model_n_points++] = point1;
							}
						}
					}
				}
				else{
					this->_model_back_3d_to_2d[this->_model_n_points][XX] = x;
					this->_model_back_3d_to_2d[this->_model_n_points][YY] = y;
				
					this->_model_projective[this->_model_n_points++] = point1;
				}
			}
		}
	} 

	bool result = this->_kinect->convert_to_realworld(	this->_model_n_points, 
														this->_model_projective,
														this->_model_realworld); 

	
	//uint8_t* ptr_clr = (uint8_t*)this->_model_color_average.data;

	//Generate PCL-3D Floor
	//uchar* ptr_mask_floor = mask_floor.data;
	//for(int y = 0; y < XN_VGA_Y_RES ; y += this->_property_manager->_3d_step) { 
	//	for(int x = 0; x < XN_VGA_X_RES ; x += this->_property_manager->_3d_step) { 
	//		//if(ptr_mask_floor[y * XN_VGA_X_RES + x]){

	//		//}
	//	}
	//}

	//Generate PCL-3D from Mirrors
	_pcl_cloud.clear();

	uchar* ptr = this->_mask_main.data;

	uint8_t* ptr_clr = (uint8_t*)this->_model_color_average.data;

	_model_cloud.clear();

	int xx, yy;
	double dist;
	
	std::vector<double> nx,ny,nz;
	for(int i = 0 ; i < this->_mirrors.size() ; ++i){
		double nx_,ny_,nz_;

		mirror = this->_mirrors[i];

		if(mirror){
			mirror->_n_points = 0;
			mirror->_plane.get_normal(&nx_,&ny_,&nz_);
			nx_ *= -1; ny_ *= -1; nz_ *= -1;

			nx.push_back(nx_);
			ny.push_back(ny_);
			nz.push_back(nz_);
		}
	}


	for(int i = 0 ; i < this->_model_n_points ; ++i){
		xx = this->_model_back_3d_to_2d[i][XX];
		yy = this->_model_back_3d_to_2d[i][YY];
		idx = yy * XN_VGA_X_RES + xx;

		if(ptr_mirror_mask[idx]){
			for(int j = 0 ; j < this->_mirrors.size() ; ++j){
				mirror = this->_mirrors[j];

				if(mirror && mirror->_area_mask.data[idx]){
					//if(this->_model_realworld[i].Z > mirror->_depth_min && this->_model_realworld[i].Z < mirror->_depth_max){
						dist = mirror->_plane.distance_to_plane( this->_model_realworld[i].X,
																 this->_model_realworld[i].Y,
																 this->_model_realworld[i].Z);

						this->_model_realworld[i].X += 2 * dist * nx[j];
						this->_model_realworld[i].Y += 2 * dist * ny[j];
						this->_model_realworld[i].Z += 2 * dist * nz[j];
					//}
				}
			}
		}


		dist = this->_floor->_plane.distance_to_plane(	this->_model_realworld[i].X,
														this->_model_realworld[i].Y,
														this->_model_realworld[i].Z);

		if(dist > this->_floor->_thresh){
			

			pcl::PointXYZRGB pt(ptr_clr[yy * XN_VGA_X_RES * 3 + xx* 3 + 2],
								ptr_clr[yy * XN_VGA_X_RES * 3 + xx* 3 + 1],
								ptr_clr[yy * XN_VGA_X_RES * 3 + xx* 3 + 0]);
						
			pt.x = this->_model_realworld[i].X;
			pt.y = this->_model_realworld[i].Y;
			pt.z = this->_model_realworld[i].Z;
			this->_model_cloud.push_back(pt);
		}
	}

	this->_property_manager->_3d_step = old_step;

	this->_property_manager->_flag_processed[PropertyManager::P_CAPTURE_SHOW] = true;
}
示例#26
0
 double randomDouble(double minVal, double maxVal)
 {
     return rng.uniform(minVal, maxVal);
 }
示例#27
0
static cv::Scalar randomScalar() {
   static cv::RNG rng(12345);
   return cv::Scalar(rng.uniform(0, 255), rng.uniform(0, 255), rng.uniform(0, 255));
}
示例#28
0
void extractPatch(cv::Mat &img, 
				  int *hull,
				  int bbW,
				  int bbH,
				  unsigned char filledColor,
				  cv::RNG &rng,
				  double noise,
				  double angle,
				  double shift,
				  double scale,
				  cv::Mat & noiseM,
				  cv::Mat &result) {

	int cpX         = (hull[0] + hull[2]) / 2;
	int cpY         = (hull[1] + hull[3]) / 2;
	cv::Mat h       = cv::Mat::eye(3, 3, CV_64FC1);
	cv::Mat temp    = cv::Mat::eye(3, 3, CV_64FC1);
	double *tempPtr = temp.ptr<double>();
	double sc;
	double ang, ca, sa;
	double shR, shC;
	double xMin, yMin, xMax, yMax;
	unsigned char *resPtr;
	double *noisePtr;
	int size;

	
	//****Translating...
	shR  = shift * bbH * (rng.uniform(1e-4, 1.)-0.5);
	shC  = shift * bbW * (rng.uniform(1e-4, 1.)-0.5);
	*(tempPtr + 2)             = shC;
	*(tempPtr + temp.cols + 2) = shR;
	h                          *= temp;
	//Reset...
	*(tempPtr + 2)              = 0.0;
	*(tempPtr +  temp.cols + 2) = 0.0;

	//****Rotating...
	ang  = 2 * CV_PI / 360.0 * angle * (rng.uniform(1e-4, 1.)-0.5);
	ca   = cos(ang);
    sa   = sin(ang);
	*tempPtr                   = ca;
	*(tempPtr + 1)             = -sa;
	*(tempPtr + temp.cols)     = sa;
	*(tempPtr + temp.cols + 1) = ca;
	h                          *= temp;
	//Reset...
	*tempPtr                   = 1.0;
	*(tempPtr + 1)             = 0.0;
	*(tempPtr + temp.cols)     = 0.0;
	*(tempPtr + temp.cols + 1) = 1.0;
	
	//****Scaling...
	sc   = 1.0 - scale*(rng.uniform(1e-4, 1.)-0.5);
	*tempPtr                   = (double)sc;
	*(tempPtr + temp.cols + 1) = (double)sc;
	h                          *= temp;
	//Reset...
	*tempPtr                   = 1.0;
	*(tempPtr + temp.cols + 1) = 1.0;
	
	//****Shifting Center of BB to (0, 0)...
	*(tempPtr + 2)             = -cpX;
	*(tempPtr + temp.cols + 2) = -cpY;
	h                          *= temp;
	
	//Now Warp the Patch...
	bbW--; 
	bbH--;
	xMin = -bbW / 2.0;
	yMin = -bbH / 2.0;
	xMax = bbW / 2.0;
	yMax = bbH / 2.0;
	warpImageROI(img,
				 xMin,
				 yMin,
				 xMax,
				 yMax,
				 bbW,
				 bbH,
				 h,
				 filledColor,
				 result.data);

	//Add Random Noise...
	rng.fill(noiseM, 
		     cv::RNG::NORMAL, 
			 cv::Mat::zeros(1,1,CV_64FC1), 
			 cv::Mat::ones(1,1,CV_64FC1));
	noiseM *= noise;
	//Here OpenCV Applies Saturation Arithmetic by Itself...
	cv::add(result, noise, result, cv::noArray(), CV_8UC1);
}
示例#29
0
 int randomInt(int minVal, int maxVal)
 {
     return rng.uniform(minVal, maxVal);
 }
示例#30
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;
}