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

Product type Paperback

Published in Jan 2020

Publisher Packt

ISBN-13 9781838826994

Length 826 pages

Edition 2nd Edition

Languages

Python

Tools

Deep Reinforcement Learning

Concepts

Chatbots

Author (1):

Maxim Lapan

View More author details

Table of Contents (28) Chapters

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

The value of the action

To make our life slightly easier, we can define different quantities, in addition to the value of the state, V(s), as the value of the action, Q(s, a). Basically, this equals the total reward we can get by executing action a in state s and can be defined via V(s). Being a much less fundamental entity than V(s), this quantity gave a name to the whole family of methods called Q-learning, because it is more convenient.

In these methods, our primary objective is to get values of Q for every pair of state and action.

Q for this state, s, and action, a, equals the expected immediate reward and the discounted long-term reward of the destination state. We also can define V(s) via Q(s, a):

This just means that the value of some state equals to the value of the maximum action we can execute from this state. Finally, we can express Q(s, a) recursively (which will be used in Chapter 6, Deep Q-Networks: