Exemple #1
0
static bool checkColision(const cv::Rect &a, const cv::Rect &b){
	if (b.contains(a.tl())) return true;
	if (b.contains(a.br())) return true;
	if (b.contains(cv::Point(a.x+a.width,a.y))) return true;
	if (b.contains(cv::Point(a.x,a.y+a.height))) return true;
	return false;
}
void drawQuadrants(cv::Point targetCoord) {
	cv::line(image, cv::Point(0, centerPoint.y), cv::Point(frameWidth, centerPoint.y), blackColor);
	cv::line(image, cv::Point(centerPoint.x, 0), cv::Point(centerPoint.x, frameHeight), blackColor);
	if (targetCoord != cv::Point(999,999)) {
		if (centerRectangle.contains(targetCoord)) {
			targetCentered = true;
			targetInQ1 = targetInQ2 = targetInQ3 = targetInQ4 = false;
			highlightAllQuadrants();
		}
		else if (targetCoord.x >= centerPoint.x) {
			if (targetCoord.y <= centerPoint.y) {
				targetInQ1 = true;
				targetInQ2 = targetInQ3 = targetInQ4 = targetCentered = false;
				highlightQuadrant(1);
			}
			else if (targetCoord.y > centerPoint.y) {
				targetInQ4 = true;
				targetInQ1 = targetInQ2 = targetInQ3 = targetCentered = false;
				highlightQuadrant(4);
			}
		}
		else if (targetCoord.x < centerPoint.x) {
			if (targetCoord.y <= centerPoint.y) {
				targetInQ2 = true;
				targetInQ1 = targetInQ3 = targetInQ4 = targetCentered = false;
				highlightQuadrant(2);
			}
			else if (targetCoord.y > centerPoint.y) {
				targetInQ3 = true;
				targetInQ1 = targetInQ2 = targetInQ4 = targetCentered = false;
				highlightQuadrant(3);
			}
		}
	}
}
    Point computeIntersect(cv::Vec4i a, cv::Vec4i b, cv::Rect ROI)
    {
        int x1 = a[0], y1 = a[1], x2 = a[2], y2 = a[3];
        int x3 = b[0], y3 = b[1], x4 = b[2], y4 = b[3];

        Point p1 = Point(x1,y1);
        Point p2 = Point(x2,y2);
        Point p3 = Point(x3,y3);
        Point p4 = Point(x4,y4);

        if( !ROI.contains(p1) || !ROI.contains(p2)
                || !ROI.contains(p3) || !ROI.contains(p4) )
            return Point(-1,-1);

        Point vec1 = p1-p2;
        Point vec2 = p3-p4;

        float vec1_norm2 = vec1.x*vec1.x + vec1.y*vec1.y;
        float vec2_norm2 = vec2.x*vec2.x + vec2.y*vec2.y;
        float cosTheta = (vec1.dot(vec2))/sqrt(vec1_norm2*vec2_norm2);

        float den = ((float)(x1-x2) * (y3-y4)) - ((y1-y2) * (x3-x4));
        if(den != 0)
        {
            cv::Point2f pt;
            pt.x = ((x1*y2 - y1*x2) * (x3-x4) - (x1-x2) * (x3*y4 - y3*x4)) / den;
            pt.y = ((x1*y2 - y1*x2) * (y3-y4) - (y1-y2) * (x3*y4 - y3*x4)) / den;

            if( !ROI.contains(pt) )
                return Point(-1,-1);

            // no-confidence metric
            float d1 = MIN( dist2(p1,pt), dist2(p2,pt) )/vec1_norm2;
            float d2 = MIN( dist2(p3,pt), dist2(p4,pt) )/vec2_norm2;

            float no_confidence_metric = MAX(sqrt(d1),sqrt(d2));

            if( no_confidence_metric < 0.5 && cosTheta < 0.707 )
                return Point(int(pt.x+0.5), int(pt.y+0.5));
        }

        return cv::Point(-1, -1);
    }
bool ImageSegmentation::toSegment(const std::vector<std::vector<cv::Point>> &contours, const std::vector<cv::Vec4i> &hierarchy, const size_t index,
                                  Segment &seg, const size_t minSize, const size_t minHoleSize, const cv::Rect &roi)
{
  seg.rect = cv::boundingRect(contours[index]);
  if(!roi.contains(seg.rect.tl()) || !roi.contains(seg.rect.br()))
  {
    // outside ROI
    return false;
  }

  seg.area = cv::contourArea(contours[index]);
  seg.childrenArea = 0;
  seg.holes = 0;

  if(seg.area < minSize)
  {
    return false;
  }

  Segment child;
  for(int32_t childIndex = hierarchy[index][2]; childIndex >= 0; childIndex = hierarchy[childIndex][0])
  {
    if(toSegment(contours, hierarchy, childIndex, child, minHoleSize, minHoleSize, roi))
    {
      seg.children.push_back(child);
      seg.area -= child.area;
      seg.childrenArea += child.area;
      ++seg.holes;
    }
  }

  if(seg.area < minSize)
  {
    return false;
  }

  seg.contour = contours[index];
  computeMoments(contours, hierarchy, index, seg);
  compute2DAttributes(seg);

  return true;
}
 bool MultiObjectTracker::sharesBoundingRect(size_t i, cv::Rect boundingRect) {
     for (size_t j = 0; j < this->kalmanTrackers.size(); j++) {
         if (i == j) {
             continue;
         }
         if (boundingRect.contains(this->kalmanTrackers[i].latestPrediction())) {
             return true;
         }
     }
     return false;
 }