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Deep Reinforcement Learning Hands-On

You're reading from   Deep Reinforcement Learning Hands-On Apply modern RL methods to practical problems of chatbots, robotics, discrete optimization, web automation, and more

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Product type Paperback
Published in Jan 2020
Publisher Packt
ISBN-13 9781838826994
Length 826 pages
Edition 2nd Edition
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Author (1):
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Maxim Lapan Maxim Lapan
Author Profile Icon Maxim Lapan
Maxim Lapan
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Table of Contents (28) Chapters Close

Preface 1. What Is Reinforcement Learning? 2. OpenAI Gym FREE CHAPTER 3. Deep Learning with PyTorch 4. The Cross-Entropy Method 5. Tabular Learning and the Bellman Equation 6. Deep Q-Networks 7. Higher-Level RL Libraries 8. DQN Extensions 9. Ways to Speed up RL 10. Stocks Trading Using RL 11. Policy Gradients – an Alternative 12. The Actor-Critic Method 13. Asynchronous Advantage Actor-Critic 14. Training Chatbots with RL 15. The TextWorld Environment 16. Web Navigation 17. Continuous Action Space 18. RL in Robotics 19. Trust Regions – PPO, TRPO, ACKTR, and SAC 20. Black-Box Optimization in RL 21. Advanced Exploration 22. Beyond Model-Free – Imagination 23. AlphaGo Zero 24. RL in Discrete Optimization 25. Multi-agent RL 26. Other Books You May Enjoy
27. Index

DDPG training and results

To train the policy using our model, we will use deep deterministic policy gradients (DDPGs), which we covered in detail in Chapter 17, Continuous Action Space. I won't spend time here showing the code, which is in Chapter18/train_ddpg.py and Chapter18/lib/ddpg.py. For exploration, the Ornstein-Uhlenbeck process was used in the same way as for the Minitaur model.

The only thing I'd like to emphasize is the size of the model, in which the actor part was intentionally reduced to meet our hardware limitations. The actor has one hidden layer with 20 neurons, giving just two matrices (not counting the bias) of 28×20 and 20×4. The input dimensionality is 28, due to observation stacking, where four past observations are passed to the model. This dimensionality reduction leads to very fast training, which can be done without a GPU involved.

To train the model, you should run the train_ddpg.py program, which accepts the following arguments...

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