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sobel_filter.py
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sobel_filter.py
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#Imports and dependencies
import numpy as np
import cv2
from math import sqrt, atan
from math import atan, degrees
import argparse
from tqdm import tqdm
pbar = tqdm(total=100)
#Constants
kernel_blur = np.array([0.11,0.11,0.11,0.11,0.11,0.11,0.11,0.11,0.11]).reshape(3,3)
kernel_conv_Y = np.array([-1,-2,-1,0,0,0,1,2,1]).reshape(3,3)
kernel_conv_X = kernel_conv_Y.transpose()
'''In the implementation of the canny filter, the following steps are implemented:
- Conversion to grayscale
- Gaussian filter for blurring and to reduce the sharpness
- Apply sobel filter in X and Y direction to detect the edges
- With the gradient obtained previously, non-maximal supression is performed
- Hystersis and double thresholding to thin the lines
'''
#The concept of convolution is used here, a kernel matrix (here, of size 3X3) convolves over the image
#This is used to blur as well as apply the sobel filter for edge-detection
def apply_convolution(img, kernel, height, weight):
pixels = []
#pixels are extracted from the image converted to grayscale
for i in range(height):
for j in range(width):
pixels.append(img[i,j])
#The pixels array is resized in accordance with the size of the image
pixels = np.array(pixels).reshape(height,width)
#To handle the edge cases, sentinel values are used
#The pixels array is bound by zeros on all edges
# 00000000
# 0PIXELS0
# 00000000
#This is done to ensure that the kernel is applied to all the pixels
#Sentinel values to ensure the edges arent missed out
#Along the rows and columns
pixels = np.insert(pixels , [0,height] , np.zeros(len(pixels[0])) , axis = 0)
pixels = np.insert(pixels , [0, width] , np.zeros((len(pixels[:, 0]) ,1)) , axis = 1)
#Convolution is applied here
convolute = []
for i in range(1,height):
for j in range(1,width):
temp = pixels[i:i+3 , j:j+3]
product = np.multiply(temp,kernel)
convolute.append(sum(sum(product)))
convolute = np.array(convolute).reshape(height-1,width-1)
return(convolute)
#In the implementation of the sobel filter, X and Y direction convolutions are obtained separately and the resultant is extracted
def sobel_filter(convoluted_X, convoluted_Y):
sobel = []
#arc = []
#Considering the square of the pixel value in X direction as pixel_X, in Y direction as pixel_Y,
#The resultant in the Z-direction is the sqrt(pixel_X + pixel_Y)
for i in range(height-2):
for j in range(width-2):
pixel_X = pow(convoluted_X[i,j], 2)
pixel_Y = pow(convoluted_Y[i,j], 2)
#pixel_X = convoluted_X[i,j]
#pixel_Y = convoluted_Y[i,j]
pixel_Z = sqrt(pixel_X + pixel_Y)
sobel.append(pixel_Z)
sobel = np.array(sobel).reshape(height-2, width-2)
return(sobel)
if __name__ == "__main__":
# construct the argument parse and parse the arguments
for i in range(1):
ap = argparse.ArgumentParser()
ap.add_argument("-i", "--image", required=True, help="path to input image")
args = vars(ap.parse_args())
pbar.update(10)
# reading the image in grayscale
img = cv2.imread((args["image"]), 0)
height = img.shape[0]
width = img.shape[1]
pbar.update(10)
#Image is blurred
blurred_img = apply_convolution(img, kernel_blur, height, width)
height = height - 1
width = width - 1
convoluted_Y = apply_convolution(blurred_img, kernel_conv_Y, height, width)
pbar.update(20)
convoluted_X = apply_convolution(blurred_img, kernel_conv_X, height, width )
pbar.update(20)
#The sobel effect is applied
sobel_filtered_image = sobel_filter(convoluted_X, convoluted_Y)
pbar.update(40)
cv2.imwrite('Sobel_filtered_image.JPG', sobel_filtered_image)
cv2.imshow("Sobel filter", sobel_filtered_image)
cv2.waitKey(0)
pbar.close()