Decentralized Reinforcement Learning: Global Decision-Making via Local Economic Transactions
July 05, 2020 ยท Declared Dead ยท ๐ International Conference on Machine Learning
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Authors
Michael Chang, Sidhant Kaushik, S. Matthew Weinberg, Thomas L. Griffiths, Sergey Levine
arXiv ID
2007.02382
Category
cs.LG: Machine Learning
Cross-listed
cs.GT,
cs.MA,
cs.NE,
stat.ML
Citations
17
Venue
International Conference on Machine Learning
Last Checked
4 months ago
Abstract
This paper seeks to establish a framework for directing a society of simple, specialized, self-interested agents to solve what traditionally are posed as monolithic single-agent sequential decision problems. What makes it challenging to use a decentralized approach to collectively optimize a central objective is the difficulty in characterizing the equilibrium strategy profile of non-cooperative games. To overcome this challenge, we design a mechanism for defining the learning environment of each agent for which we know that the optimal solution for the global objective coincides with a Nash equilibrium strategy profile of the agents optimizing their own local objectives. The society functions as an economy of agents that learn the credit assignment process itself by buying and selling to each other the right to operate on the environment state. We derive a class of decentralized reinforcement learning algorithms that are broadly applicable not only to standard reinforcement learning but also for selecting options in semi-MDPs and dynamically composing computation graphs. Lastly, we demonstrate the potential advantages of a society's inherent modular structure for more efficient transfer learning.
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