# -*- coding: utf-8 -*- """ Created on Sun May 17 14:53:24 2020 @author: serdarhelli """ import cv2 import numpy as np from skimage.feature import peak_local_max from skimage.morphology import watershed from scipy import ndimage import matplotlib.pyplot as plt from imutils import perspective from imutils import contours from scipy.spatial import distance as dist def midpoint(ptA, ptB): return ((ptA[0] + ptB[0]) * 0.5, (ptA[1] + ptB[1]) * 0.5) # Load in image, convert to gray scale, and Otsu's threshold kernel =( np.ones((3,3), dtype=np.float32)) image = cv2.imread('pred_image') image=cv2.morphologyEx(image, cv2.MORPH_OPEN, kernel) gray = cv2.cvtColor(image, cv2.COLOR_BGR2GRAY) thresh = cv2.threshold(gray, 0, 255, cv2.THRESH_BINARY + cv2.THRESH_OTSU)[1] erosion = cv2.erode(thresh,kernel,iterations =5) gradient = cv2.morphologyEx(erosion, cv2.MORPH_GRADIENT, kernel) # Compute Euclidean distance from every binary pixel # to the nearest zero pixel then find peaks distance_map = ndimage.distance_transform_edt(erosion) distance_map = ndimage.maximum_filter(distance_map, size=15, mode='constant') local_max = peak_local_max(distance_map, indices=False, min_distance=40, labels=thresh) # Perform connected component analysis then apply Watershed markers = ndimage.label(local_max, structure=np.ones((3, 3)))[0] labels = watershed(-distance_map, markers, mask=thresh) # Iterate through unique labels total_area = 0 a=np.unique(labels) area=np.zeros(len(a)) for label in a: if label == 0: continue # Create a mask mask = np.zeros(thresh.shape, dtype="uint8") mask[labels == label] = 255 # Find contours and determine contour area cnts,hieararch = cv2.findContours(mask.copy(), cv2.RETR_EXTERNAL, cv2.CHAIN_APPROX_SIMPLE) cnts = cnts[0] (x,y),radius = cv2.minEnclosingCircle(cnts) rect = cv2.minAreaRect(cnts) box = cv2.boxPoints(rect) box = np.array(box, dtype="int") box = perspective.order_points(box) color1 = (list(np.random.choice(range(256), size=3))) color =[int(color1[0]), int(color1[1]), int(color1[2])] cv2.drawContours(image,[box.astype("int")],0,color,2) (tl,tr,br,bl)=box (tltrX,tltrY)=midpoint(tl,tr) (blbrX,blbrY)=midpoint(bl,br) # compute the midpoint between the top-left and top-right points, # followed by the midpoint between the top-righ and bottom-right (tlblX,tlblY)=midpoint(tl,bl) (trbrX,trbrY)=midpoint(tr,br) # draw the midpoints on the image cv2.circle(image, (int(tltrX), int(tltrY)), 5, (255, 0, 0), -1) cv2.circle(image, (int(blbrX), int(blbrY)), 5, (255, 0, 0), -1) cv2.circle(image, (int(tlblX), int(tlblY)), 5, (255, 0, 0), -1) cv2.circle(image, (int(trbrX), int(trbrY)), 5, (255, 0, 0), -1) cv2.line(image, (int(tltrX), int(tltrY)), (int(blbrX), int(blbrY)),color, 2) cv2.line(image, (int(tlblX), int(tlblY)), (int(trbrX), int(trbrY)),color, 2) dA = dist.euclidean((tltrX, tltrY), (blbrX, blbrY)) dB = dist.euclidean((tlblX, tlblY), (trbrX, trbrY)) ##your pixel size of your x_ray image pixelsPerMetric=0.096 dimA = dA * pixelsPerMetric dimB = dB *pixelsPerMetric cv2.putText(image, "{:.1f}mm".format(dimA),(int(tltrX - 15), int(tltrY - 10)), cv2.FONT_HERSHEY_SIMPLEX,0.65, color, 2) cv2.putText(image, "{:.1f}mm".format(dimB),(int(trbrX + 10), int(trbrY)), cv2.FONT_HERSHEY_SIMPLEX,0.65, color, 2) cv2.imwrite('water_pred_image',image) cv2.waitKey()