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Deep Reinforcement Learning Hands-On

Deep Reinforcement Learning Hands-On

By : Maxim Lapan
4.3 (38)
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Deep Reinforcement Learning Hands-On

Deep Reinforcement Learning Hands-On

4.3 (38)
By: Maxim Lapan

Overview of this book

Deep Reinforcement Learning Hands-On, Second Edition is an updated and expanded version of the bestselling guide to the very latest reinforcement learning (RL) tools and techniques. It provides you with an introduction to the fundamentals of RL, along with the hands-on ability to code intelligent learning agents to perform a range of practical tasks. With six new chapters devoted to a variety of up-to-the-minute developments in RL, including discrete optimization (solving the Rubik's Cube), multi-agent methods, Microsoft's TextWorld environment, advanced exploration techniques, and more, you will come away from this book with a deep understanding of the latest innovations in this emerging field. In addition, you will gain actionable insights into such topic areas as deep Q-networks, policy gradient methods, continuous control problems, and highly scalable, non-gradient methods. You will also discover how to build a real hardware robot trained with RL for less than $100 and solve the Pong environment in just 30 minutes of training using step-by-step code optimization. In short, Deep Reinforcement Learning Hands-On, Second Edition, is your companion to navigating the exciting complexities of RL as it helps you attain experience and knowledge through real-world examples.
Table of Contents (28 chapters)
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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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