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Mastering PyTorch

You're reading from   Mastering PyTorch Build powerful neural network architectures using advanced PyTorch 1.x features

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Product type Paperback
Published in Feb 2021
Publisher Packt
ISBN-13 9781789614381
Length 450 pages
Edition 1st Edition
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Author (1):
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Ashish Ranjan Jha Ashish Ranjan Jha
Author Profile Icon Ashish Ranjan Jha
Ashish Ranjan Jha
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Table of Contents (20) Chapters Close

Preface 1. Section 1: PyTorch Overview
2. Chapter 1: Overview of Deep Learning using PyTorch FREE CHAPTER 3. Chapter 2: Combining CNNs and LSTMs 4. Section 2: Working with Advanced Neural Network Architectures
5. Chapter 3: Deep CNN Architectures 6. Chapter 4: Deep Recurrent Model Architectures 7. Chapter 5: Hybrid Advanced Models 8. Section 3: Generative Models and Deep Reinforcement Learning
9. Chapter 6: Music and Text Generation with PyTorch 10. Chapter 7: Neural Style Transfer 11. Chapter 8: Deep Convolutional GANs 12. Chapter 9: Deep Reinforcement Learning 13. Section 4: PyTorch in Production Systems
14. Chapter 10: Operationalizing PyTorch Models into Production 15. Chapter 11: Distributed Training 16. Chapter 12: PyTorch and AutoML 17. Chapter 13: PyTorch and Explainable AI 18. Chapter 14: Rapid Prototyping with PyTorch 19. Other Books You May Enjoy

Discussing ResNet and DenseNet architectures

In the previous section, we explored the Inception models, which had a reduced number of model parameters as the number of layers increased, thanks to the 1x1 convolutions and global average pooling. Furthermore, auxiliary classifiers were used to combat the vanishing gradient problem.

ResNet introduced the concept of skip connections. This simple yet effective trick overcomes the problem of both parameter overflow and vanishing gradients. The idea, as shown in the following diagram, is quite simple. The input is first passed through a non-linear transformation (convolutions followed by non-linear activations) and then the output of this transformation (referred to as the residual) is added to the original input. Each block of such computation is called a residual block, hence the name of the model – residual network or ResNet.

Figure 3.26 – Skip connections

Figure 3.26 – Skip connections

Using these skip (or shortcut) connections...

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