Python/digital_image_processing/morphological_operations/erosion_operation.py

import numpy as np
from PIL import Image


def rgb2gray(rgb: np.array) -> np.array:
    """
    Return gray image from rgb image
    >>> rgb2gray(np.array([[[127, 255, 0]]]))
    array([[187.6453]])
    >>> rgb2gray(np.array([[[0, 0, 0]]]))
    array([[0.]])
    >>> rgb2gray(np.array([[[2, 4, 1]]]))
    array([[3.0598]])
    >>> rgb2gray(np.array([[[26, 255, 14], [5, 147, 20], [1, 200, 0]]]))
    array([[159.0524,  90.0635, 117.6989]])
    """
    r, g, b = rgb[:, :, 0], rgb[:, :, 1], rgb[:, :, 2]
    return 0.2989 * r + 0.5870 * g + 0.1140 * b


def gray2binary(gray: np.array) -> np.array:
    """
    Return binary image from gray image
    >>> gray2binary(np.array([[127, 255, 0]]))
    array([[False,  True, False]])
    >>> gray2binary(np.array([[0]]))
    array([[False]])
    >>> gray2binary(np.array([[26.2409, 4.9315, 1.4729]]))
    array([[False, False, False]])
    >>> gray2binary(np.array([[26, 255, 14], [5, 147, 20], [1, 200, 0]]))
    array([[False,  True, False],
           [False,  True, False],
           [False,  True, False]])
    """
    return (127 < gray) & (gray <= 255)


def erosion(image: np.array, kernel: np.array) -> np.array:
    """
    Return eroded image
    >>> erosion(np.array([[True, True, False]]), np.array([[0, 1, 0]]))
    array([[False, False, False]])
    >>> erosion(np.array([[True, False, False]]), np.array([[1, 1, 0]]))
    array([[False, False, False]])
    """
    output = np.zeros_like(image)
    image_padded = np.zeros(
        (image.shape[0] + kernel.shape[0] - 1, image.shape[1] + kernel.shape[1] - 1)
    )

    # Copy image to padded image
    image_padded[kernel.shape[0] - 2 : -1 :, kernel.shape[1] - 2 : -1 :] = image

    # Iterate over image & apply kernel
    for x in range(image.shape[1]):
        for y in range(image.shape[0]):
            summation = (
                kernel * image_padded[y : y + kernel.shape[0], x : x + kernel.shape[1]]
            ).sum()
            output[y, x] = int(summation == 5)
    return output


# kernel to be applied
structuring_element = np.array([[0, 1, 0], [1, 1, 1], [0, 1, 0]])

if __name__ == "__main__":
    # read original image
    image = np.array(Image.open(r"..\image_data\lena.jpg"))
    # Apply erosion operation to a binary image
    output = erosion(gray2binary(rgb2gray(image)), structuring_element)
    # Save the output image
    pil_img = Image.fromarray(output).convert("RGB")
    pil_img.save("result_erosion.png")
Added morphological operations, fixes: #5197 (#5199) * Added morphological operations, fixes: #5197 * Added dilation tests and type hints * Added erosion tests and type hints * fixes: TheAlgorithms#5197 * fixes: TheAlgorithms#5197 * Update erosion_operation.py * made suggested changes in dilation * made suggested changes in erosion * made suggested changes in dilation * removed extra spaces in the tests * removed extra spaces in the tests 2021-10-16 14:32:40 +00:00			`import numpy as np`
			`from PIL import Image`


			`def rgb2gray(rgb: np.array) -> np.array:`
			`"""`
			`Return gray image from rgb image`
			`>>> rgb2gray(np.array([[[127, 255, 0]]]))`
			`array([[187.6453]])`
			`>>> rgb2gray(np.array([[[0, 0, 0]]]))`
			`array([[0.]])`
			`>>> rgb2gray(np.array([[[2, 4, 1]]]))`
			`array([[3.0598]])`
			`>>> rgb2gray(np.array([[[26, 255, 14], [5, 147, 20], [1, 200, 0]]]))`
			`array([[159.0524, 90.0635, 117.6989]])`
			`"""`
			`r, g, b = rgb[:, :, 0], rgb[:, :, 1], rgb[:, :, 2]`
			`return 0.2989 * r + 0.5870 * g + 0.1140 * b`


			`def gray2binary(gray: np.array) -> np.array:`
			`"""`
			`Return binary image from gray image`
			`>>> gray2binary(np.array([[127, 255, 0]]))`
			`array([[False, True, False]])`
			`>>> gray2binary(np.array([[0]]))`
			`array([[False]])`
			`>>> gray2binary(np.array([[26.2409, 4.9315, 1.4729]]))`
			`array([[False, False, False]])`
			`>>> gray2binary(np.array([[26, 255, 14], [5, 147, 20], [1, 200, 0]]))`
			`array([[False, True, False],`
			`[False, True, False],`
			`[False, True, False]])`
			`"""`
			`return (127 < gray) & (gray <= 255)`


			`def erosion(image: np.array, kernel: np.array) -> np.array:`
			`"""`
			`Return eroded image`
			`>>> erosion(np.array([[True, True, False]]), np.array([[0, 1, 0]]))`
			`array([[False, False, False]])`
			`>>> erosion(np.array([[True, False, False]]), np.array([[1, 1, 0]]))`
			`array([[False, False, False]])`
			`"""`
			`output = np.zeros_like(image)`
			`image_padded = np.zeros(`
			`(image.shape[0] + kernel.shape[0] - 1, image.shape[1] + kernel.shape[1] - 1)`
			`)`

			`# Copy image to padded image`
			`image_padded[kernel.shape[0] - 2 : -1 :, kernel.shape[1] - 2 : -1 :] = image`

			`# Iterate over image & apply kernel`
			`for x in range(image.shape[1]):`
			`for y in range(image.shape[0]):`
			`summation = (`
			`kernel * image_padded[y : y + kernel.shape[0], x : x + kernel.shape[1]]`
			`).sum()`
			`output[y, x] = int(summation == 5)`
			`return output`


			`# kernel to be applied`
			`structuring_element = np.array([[0, 1, 0], [1, 1, 1], [0, 1, 0]])`

			`if __name__ == "__main__":`
			`# read original image`
			`image = np.array(Image.open(r"..\image_data\lena.jpg"))`
			`# Apply erosion operation to a binary image`
			`output = erosion(gray2binary(rgb2gray(image)), structuring_element)`
			`# Save the output image`
			`pil_img = Image.fromarray(output).convert("RGB")`
			`pil_img.save("result_erosion.png")`