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You're reading from Hands-On Image Processing with Python Expert techniques for advanced image analysis and effective interpretation of image data

Product type Paperback

Published in Nov 2018

Publisher Packt

ISBN-13 9781789343731

Length 492 pages

Edition 1st Edition

Languages

Processing

Tools

Keras

Concepts

Computer Vision

Author (1):

Sandipan Dey

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Table of Contents (20) Chapters

Title Page

Dedication

About Packt

Contributors

Preface

1. Getting Started with Image Processing

2. Sampling, Fourier Transform, and Convolution FREE CHAPTER

3. Convolution and Frequency Domain Filtering

4. Image Enhancement

5. Image Enhancement Using Derivatives

6. Morphological Image Processing

7. Extracting Image Features and Descriptors

8. Image Segmentation

9. Classical Machine Learning Methods in Image Processing

10. Deep Learning in Image Processing - Image Classification

11. Deep Learning in Image Processing - Object Detection, and more

12. Additional Problems in Image Processing

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Index

Face morphing

In Chapter 1, Getting Started with Image Processing, we discussed a naive face morphing technique based on simple α-blending, which looks terrible if the faces to be morphed are not aligned.

Let's conclude the last chapter by discussing a sophisticated face morphing technique, namely Beier-Neely morphing, which visually looks way smoother and better than α-blending for non-aligned faces. Here is the algorithm:

Read in two image files, A and B.
Specify the correspondence between source image and destination image interactively (by computing facial key points with PyStasm) using a set of line segment pairs. Save the line segment pair to lines file.
Read the lines file. The lines file contains the line segment pairs S_i^A, S_i^B.
Compute destination line segments by linearly interpolating between S_i^Aand S_i^Bby warp fraction. These line segments define the destination shape.
Warp image A to its destination shape, computing a new image A'.
Warp picture B to its destination shape, computing...