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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

Auto-encoding

Auto-encoders (AEs) are a special type of encoders-decoders. As shown in Figure 6-1, their input and target domains are the same, so their goal is to properly encode and then decode images without impacting their quality, despite their bottleneck (their latent space of lower dimensionality). The inputs are reduced to a compressed representation (as feature vectors). If an original input is requested later on, it can be reconstructed from its compressed representation by the decoder.

JPEG tools can thus be called AEs, as their goal is to encode images and then decode them back without losing too much of their quality. The distance between the input and output data is the typical loss to minimize for auto-encoding algorithms. For images, this distance can simply be computed as the cross-entropy loss, or as the L1/L2 loss (Manhattan and Euclidean distances, respectively) between the input images and resulting images (as illustrated in Chapter 3, Modern Neural Networks...

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