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Python Image Processing Cookbook

You're reading from   Python Image Processing Cookbook Over 60 recipes to help you perform complex image processing and computer vision tasks with ease

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Product type Paperback
Published in Apr 2020
Publisher Packt
ISBN-13 9781789537147
Length 438 pages
Edition 1st Edition
Languages
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Author (1):
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Sandipan Dey Sandipan Dey
Author Profile Icon Sandipan Dey
Sandipan Dey
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Toc

Table of Contents (11) Chapters Close

Preface 1. Image Manipulation and Transformation 2. Image Enhancement FREE CHAPTER 3. Image Restoration 4. Binary Image Processing 5. Image Registration 6. Image Segmentation 7. Image Classification 8. Object Detection in Images 9. Face Recognition, Image Captioning, and More 10. Other Books You May Enjoy

Applying perspective transformation and homography

The goal of perspective (projective) transform is to estimate homography (a matrix, H) from point correspondences between two images. Since the matrix has a Depth Of Field (DOF) of eight, you need at least four pairs of points to compute the homography matrix from two images. The following diagram shows the basic concepts required to compute the homography matrix:

Fortunately, we don't need to compute the SVD and the H matrix is computed automatically by the ProjectiveTransform function from the scikit-image transform module. In this recipe, we will use this function to implement homography.

Getting ready

We will use a humming bird's image and an image of an astronaut on the moon (taken from NASA's public domain images) as input images in this recipe. Again, let's start by importing the required libraries as usual:

from skimage.transform import ProjectiveTransform
from skimage.io import imread
import numpy as np
import matplotlib.pylab as plt

How to do it...

Perform the following steps to apply a projective transformation to an image using the transform module from scikit-image:

  1. First, read the source image and create a destination image with the np.zeros() function:
im_src = (imread('images/humming2.png'))
height, width, dim = im_src.shape
im_dst = np.zeros((height, width, dim))
  1. Create an instance of the ProjectiveTransform class:
pt = ProjectiveTransform()

  1. You just need to provide four pairs of matching points between the source and destination images to estimate the homography matrix, H, automatically for you. Here, the four corners of the destination image and the four corners of the input hummingbird are provided as matching points, as shown in the following code block:
src = np.array([[ 295., 174.],
[ 540., 146. ],
[ 400., 777.],
[ 60., 422.]])
dst = np.array([[ 0., 0.],
[height-1, 0.],
[height-1, width-1],
[ 0., width-1]])
  1. Obtain the source pixel index corresponding to each pixel index in the destination:
x, y = np.mgrid[:height, :width]
dst_indices = np.hstack((x.reshape(-1, 1), y.reshape(-1,1)))
src_indices = np.round(pt.inverse(dst_indices), 0).astype(int)
valid_idx = np.where((src_indices[:,0] < height) & (src_indices[:,1] < width) &
(src_indices[:,0] >= 0) & (src_indices[:,1] >= 0))
dst_indicies_valid = dst_indices[valid_idx]
src_indicies_valid = src_indices[valid_idx]
  1. Copy pixels from the source to the destination images:
im_dst[dst_indicies_valid[:,0],dst_indicies_valid[:,1]] =       
im_src[src_indicies_valid[:,0],src_indicies_valid[:,1]]

If you run the preceding code snippets, you will get an output like the following screenshot:

The next screenshot shows the source image of an astronaut on the moon and the destination image of the canvas. Again, by providing four pairs of mapping points in between the source (corner points) and destination (corners of the canvas), the task is pretty straightforward:

The following screenshot shows the output image after the projective transform:

How it works...

In both of the preceding cases, the input image is projected onto the desired location of the output image.

A ProjectiveTransform object is needed to be created first to apply perspective transform to an image.

A set of 4-pixel positions from the source image and corresponding matching pixel positions in the destination image are needed to be passed to the estimate() function along with the object instance and this computes the homography matrix, H (and returns True if it can be computed).

The inverse() function is to be called on the object and this will give you the source pixel indices corresponding to all destination pixel indices.

There's more...

You can use the warp() function (instead of the inverse() function) to implement homography/projective transform.

See also

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