OpenCV  3.4.20
Open Source Computer Vision
Contours : More Functions

Prev Tutorial: Contour Properties

Next Tutorial: Contours Hierarchy

Goal

Theory and Code

1. Convexity Defects

We saw what is convex hull in second chapter about contours. Any deviation of the object from this hull can be considered as convexity defect.We can visualize it using an image. We draw a line joining start point and end point, then draw a circle at the farthest point.

Note
Remember we have to pass returnPoints = False while finding convex hull, in order to find convexity defects.

We use the function: cv.convexityDefects (contour, convexhull, convexityDefect)

Parameters
contourinput contour.
convexhullconvex hull obtained using convexHull that should contain indices of the contour points that make the hull
convexityDefectthe output vector of convexity defects. Each convexity defect is represented as 4-element(start_index, end_index, farthest_pt_index, fixpt_depth), where indices are 0-based indices in the original contour of the convexity defect beginning, end and the farthest point, and fixpt_depth is fixed-point approximation (with 8 fractional bits) of the distance between the farthest contour point and the hull. That is, to get the floating-point value of the depth will be fixpt_depth/256.0.

Try it

2. Point Polygon Test

This function finds the shortest distance between a point in the image and a contour. It returns the distance which is negative when point is outside the contour, positive when point is inside and zero if point is on the contour.

We use the function: cv.pointPolygonTest (contour, pt, measureDist)

Parameters
contourinput contour.
ptpoint tested against the contour.
measureDistif true, the function estimates the signed distance from the point to the nearest contour edge. Otherwise, the function only checks if the point is inside a contour or not.
let dist = cv.pointPolygonTest(cnt, new cv.Point(50, 50), true);

3. Match Shapes

OpenCV comes with a function cv.matchShapes() which enables us to compare two shapes, or two contours and returns a metric showing the similarity. The lower the result, the better match it is. It is calculated based on the hu-moment values. Different measurement methods are explained in the docs.

We use the function: cv.matchShapes (contour1, contour2, method, parameter)

Parameters
contour1first contour or grayscale image.
contour2second contour or grayscale image.
methodcomparison method, see cv::ShapeMatchModes
parametermethod-specific parameter(not supported now).

Try it