Here, we use morphological reconstruction to create a background image, which we can subtract from the original image to isolate bright features (regional maxima).
First we try reconstruction by dilation starting at the edges of the image. We initialize a seed image to the minimum intensity of the image, and set its border to be the pixel values in the original image. These maximal pixels will get dilated in order to reconstruct the background image.
import numpy as np
from scipy.ndimage import gaussian_filter
import matplotlib.pyplot as plt
from skimage import data
from skimage import img_as_float
from skimage.morphology import reconstruction
# Convert to float: Important for subtraction later which won't work with uint8
image = img_as_float(data.coins())
image = gaussian_filter(image, 1)
seed = np.copy(image)
seed[1:-1, 1:-1] = image.min()
mask = image
dilated = reconstruction(seed, mask, method='dilation')
Subtracting the dilated image leaves an image with just the coins and a flat, black background, as shown below.
fig, (ax1, ax2, ax3) = plt.subplots(ncols=3, figsize=(8, 2.5))
ax1.imshow(image)
ax1.set_title('original image')
ax1.axis('off')
ax2.imshow(dilated, vmin=image.min(), vmax=image.max())
ax2.set_title('dilated')
ax2.axis('off')
ax3.imshow(image - dilated)
ax3.set_title('image - dilated')
ax3.axis('off')
fig.tight_layout()
Although the features (i.e. the coins) are clearly isolated, the coins surrounded by a bright background in the original image are dimmer in the subtracted image. We can attempt to correct this using a different seed image.
Instead of creating a seed image with maxima along the image border, we can use the features of the image itself to seed the reconstruction process. Here, the seed image is the original image minus a fixed value, h.
h = 0.4
seed = image - h
dilated = reconstruction(seed, mask, method='dilation')
hdome = image - dilated
To get a feel for the reconstruction process, we plot the intensity of the mask, seed, and dilated images along a slice of the image (indicated by red line).
fig, (ax1, ax2, ax3) = plt.subplots(ncols=3, figsize=(8, 2.5))
yslice = 197
ax1.plot(mask[yslice], '0.5', label='mask')
ax1.plot(seed[yslice], 'k', label='seed')
ax1.plot(dilated[yslice], 'r', label='dilated')
ax1.set_ylim(-0.2, 2)
ax1.set_title('image slice')
ax1.set_xticks([])
ax1.legend()
ax2.imshow(dilated, vmin=image.min(), vmax=image.max())
ax2.axhline(yslice, color='r', alpha=0.4)
ax2.set_title('dilated')
ax2.axis('off')
ax3.imshow(hdome)
ax3.axhline(yslice, color='r', alpha=0.4)
ax3.set_title('image - dilated')
ax3.axis('off')
fig.tight_layout()
plt.show()
As you can see in the image slice, each coin is given a different baseline intensity in the reconstructed image; this is because we used the local intensity (shifted by h) as a seed value. As a result, the coins in the subtracted image have similar pixel intensities. The final result is known as the h-dome of an image since this tends to isolate regional maxima of height h. This operation is particularly useful when your images are unevenly illuminated.
Python source code: download (generated using skimage 0.10dev)
IPython Notebook: download (generated using skimage 0.10dev)