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Hands-On Q-Learning with Python

You're reading from   Hands-On Q-Learning with Python Practical Q-learning with OpenAI Gym, Keras, and TensorFlow

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Product type Paperback
Published in Apr 2019
Publisher Packt
ISBN-13 9781789345803
Length 212 pages
Edition 1st Edition
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Author (1):
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Nazia Habib Nazia Habib
Author Profile Icon Nazia Habib
Nazia Habib
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Table of Contents (14) Chapters Close

Preface 1. Section 1: Q-Learning: A Roadmap
2. Brushing Up on Reinforcement Learning Concepts FREE CHAPTER 3. Getting Started with the Q-Learning Algorithm 4. Setting Up Your First Environment with OpenAI Gym 5. Teaching a Smartcab to Drive Using Q-Learning 6. Section 2: Building and Optimizing Q-Learning Agents
7. Building Q-Networks with TensorFlow 8. Digging Deeper into Deep Q-Networks with Keras and TensorFlow 9. Section 3: Advanced Q-Learning Challenges with Keras, TensorFlow, and OpenAI Gym
10. Decoupling Exploration and Exploitation in Multi-Armed Bandits 11. Further Q-Learning Research and Future Projects 12. Assessments 13. Other Books You May Enjoy

Chapter 5, Building Q-Networks with TensorFlow

  1. An extensional definition is given in terms of examples. An intensional definition is a dictionary definition, given in terms of a high-level description.
  2. Feedforward is the process by which values of individual nodes in a network are calculated, and the values are then multiplied by network weights and used as inputs to other nodes in the next layer of the network.
  3. The weights in a neural network are used to calculate values to be propagated through the network. They function as coefficients and are updated through backpropagation to improve the accuracy of the network.
  1. Gradient descent is an optimization function that adjusts its parameters iteratively to minimize error. It is used in backpropagation to adjust the weights on a neural network to correctly approximate the desired function.
  2. Backpropagation is used to train neural...
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