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Mastering TensorFlow 1.x

You're reading from   Mastering TensorFlow 1.x Advanced machine learning and deep learning concepts using TensorFlow 1.x and Keras

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Product type Paperback
Published in Jan 2018
Publisher Packt
ISBN-13 9781788292061
Length 474 pages
Edition 1st Edition
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Toc

Table of Contents (21) Chapters Close

Preface 1. TensorFlow 101 2. High-Level Libraries for TensorFlow FREE CHAPTER 3. Keras 101 4. Classical Machine Learning with TensorFlow 5. Neural Networks and MLP with TensorFlow and Keras 6. RNN with TensorFlow and Keras 7. RNN for Time Series Data with TensorFlow and Keras 8. RNN for Text Data with TensorFlow and Keras 9. CNN with TensorFlow and Keras 10. Autoencoder with TensorFlow and Keras 11. TensorFlow Models in Production with TF Serving 12. Transfer Learning and Pre-Trained Models 13. Deep Reinforcement Learning 14. Generative Adversarial Networks 15. Distributed Models with TensorFlow Clusters 16. TensorFlow Models on Mobile and Embedded Platforms 17. TensorFlow and Keras in R 18. Debugging TensorFlow Models 19. Tensor Processing Units
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Simple RNN in TensorFlow

The workflow to define and train a simple RNN in TensorFlow is as follows:

  1. Define the hyper-parameters for the model:
state_size = 4
n_epochs = 100
n_timesteps = n_x
learning_rate = 0.1

The new hyper-parameter here is the state_size. The state_size represents the number of weight vectors of an RNN cell.

  1. Define the placeholders for X and Y parameters for the model. The shape of X placeholder is (batch_size, number_of_input_timesteps, number_of_inputs) and the shape of Y placeholder is (batch_size, number_of_output_timesteps, number_of_outputs). For batch_size, we use None so that we can input the batch of any size later.
X_p = tf.placeholder(tf.float32, [None, n_timesteps, n_x_vars], 
name='X_p')
Y_p = tf.placeholder(tf.float32, [None, n_timesteps, n_y_vars],
name='Y_p')
  1. Transform the input placeholder X_p into a list of tensors...
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