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Hands-On Computer Vision with TensorFlow 2

You're reading from   Hands-On Computer Vision with TensorFlow 2 Leverage deep learning to create powerful image processing apps with TensorFlow 2.0 and Keras

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Product type Paperback
Published in May 2019
Publisher Packt
ISBN-13 9781788830645
Length 372 pages
Edition 1st Edition
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Authors (2):
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Eliot Andres Eliot Andres
Author Profile Icon Eliot Andres
Eliot Andres
Benjamin Planche Benjamin Planche
Author Profile Icon Benjamin Planche
Benjamin Planche
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Table of Contents (16) Chapters Close

Preface 1. Section 1: TensorFlow 2 and Deep Learning Applied to Computer Vision FREE CHAPTER
2. Computer Vision and Neural Networks 3. TensorFlow Basics and Training a Model 4. Modern Neural Networks 5. Section 2: State-of-the-Art Solutions for Classic Recognition Problems
6. Influential Classification Tools 7. Object Detection Models 8. Enhancing and Segmenting Images 9. Section 3: Advanced Concepts and New Frontiers of Computer Vision
10. Training on Complex and Scarce Datasets 11. Video and Recurrent Neural Networks 12. Optimizing Models and Deploying on Mobile Devices 13. Migrating from TensorFlow 1 to TensorFlow 2 14. Assessments 15. Other Books You May Enjoy

Respecting boundaries

If elements captured by a semantic mask are well-separated/non-overlapping, splitting the masks to distinguish each instance is not too complicated a task. Plenty of algorithms are available to estimate the contours of distinct blobs in binary matrices and/or to provide a separate mask for each blob. For multi-class instance segmentation, this process can just be repeated for each class mask returned by object segmentation methods, splitting them further into instances.

But precise semantic masks should first be obtained, or elements too close to each other may be returned as a single blob. So, how can we ensure that segmentation models put enough attention into generating masks with precise contours, at least for non-overlapping elements? We know the answer already—the only way to teach networks to do something specific is to adapt their training loss accordingly.

U-Net was developed for biomedical applications, to segment neuronal structures in microscope...

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