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Deep Learning with TensorFlow 2 and Keras

You're reading from   Deep Learning with TensorFlow 2 and Keras Regression, ConvNets, GANs, RNNs, NLP, and more with TensorFlow 2 and the Keras API

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Product type Paperback
Published in Dec 2019
Publisher Packt
ISBN-13 9781838823412
Length 646 pages
Edition 2nd Edition
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Authors (3):
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Dr. Amita Kapoor Dr. Amita Kapoor
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Dr. Amita Kapoor
Sujit Pal Sujit Pal
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Sujit Pal
Antonio Gulli Antonio Gulli
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Antonio Gulli
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Table of Contents (19) Chapters Close

Preface 1. Neural Network Foundations with TensorFlow 2.0 2. TensorFlow 1.x and 2.x FREE CHAPTER 3. Regression 4. Convolutional Neural Networks 5. Advanced Convolutional Neural Networks 6. Generative Adversarial Networks 7. Word Embeddings 8. Recurrent Neural Networks 9. Autoencoders 10. Unsupervised Learning 11. Reinforcement Learning 12. TensorFlow and Cloud 13. TensorFlow for Mobile and IoT and TensorFlow.js 14. An introduction to AutoML 15. The Math Behind Deep Learning 16. Tensor Processing Unit 17. Other Books You May Enjoy
18. Index

Thinking about backpropagation and RNNs

As you remember from Chapter 8, Recurrent Neural Networks, the basic equation for an RNN is , the final prediction is at step t, the correct value is yt, and the error E is the cross-entropy. Here U, V, W are learning parameters used for the RNNs' equations. These equations can be visualized as in Figure 16 where we unroll the recurrency. The core idea is that total error is just the sum of the errors at each time step.

If we used SGD, we need to sum the errors and the gradients at each timestep for one given training example:

Figure 16: Recurrent neural network unrolled with equations

We are not going to write all the tedious math behind all the gradients, but rather focus only on a few peculiar cases. For instance, with math computations similar to the one made in the previous chapters, it can be proven by using the chain rule that the gradient for V depends only on the value at the current timestep s3, y3 and :

However...

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