How to implement connected component labeling in python with open cv? This is an image example:
I need connected component labeling to separate objects on a black and white image.
The OpenCV 3.0 docs for
connectedComponents() don't mention Python but it actually is implemented. See for e.g. this SO question. On OpenCV 3.4.0 and above, the docs do include the Python signatures, as can be seen on the current master docs.
The function call is simple:
num_labels, labels_im = cv2.connectedComponents(img) and you can specify a parameter
connectivity to check for 4- or 8-way (default) connectivity. The difference is that 4-way connectivity just checks the top, bottom, left, and right pixels and sees if they connect; 8-way checks if any of the eight neighboring pixels connect. If you have diagonal connections (like you do here) you should specify
connectivity=8. Note that it just numbers each component and gives them increasing integer labels starting at 0. So all the zeros are connected, all the ones are connected, etc. If you want to visualize them, you can map those numbers to specific colors. I like to map them to different hues, combine them into an HSV image, and then convert to BGR to display. Here's an example with your image:
import cv2 import numpy as np img = cv2.imread('eGaIy.jpg', 0) img = cv2.threshold(img, 127, 255, cv2.THRESH_BINARY) # ensure binary num_labels, labels_im = cv2.connectedComponents(img) def imshow_components(labels): # Map component labels to hue val label_hue = np.uint8(179*labels/np.max(labels)) blank_ch = 255*np.ones_like(label_hue) labeled_img = cv2.merge([label_hue, blank_ch, blank_ch]) # cvt to BGR for display labeled_img = cv2.cvtColor(labeled_img, cv2.COLOR_HSV2BGR) # set bg label to black labeled_img[label_hue==0] = 0 cv2.imshow('labeled.png', labeled_img) cv2.waitKey() imshow_components(labels_im)
My adaptation of the CCL in 2D is:
1) Convert the image into a 1/0 image, with 1 being the object pixels and 0 being the background pixels.
2) Make a 2 pass CCL algorithm by implementing the Union-Find algorithm with pass compression. You can see more here.
In the First pass in this CCL implementation, you check the neighbor pixels, in the case your target pixel is an object pixel, and compare their label between them so that you can generate equivalences between them. You assign the least label, of those neighbor pixels which are objects pixels (label>0) to your target pixel. In this way, you are not only assigning an object label to your target pixesl (label>0) but also creating a list of equivalences.
2) In the second pass, you go through all the pixels, and change their previous label by the label of its parent label by just looking into the equivalent table stored in your Union-Find class.
3)I implemented an additional pass to make the labels follow a sequential order (1,2,3,4....) instead of a random order (23,45,1,...). That involves changing the labels "name" just for aesthetic purposes.