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Byzantine-Resilient Decentralized Policy Evaluation With Linear Function Approximation

Zhaoxian Wu, Han Shen, Tianyi Chen, Qing Ling

2021IEEE Transactions on Signal Processing21 citationsDOIOpen Access PDF

Abstract

In this paper, we consider the policy evaluation problem in reinforcement learning with agents on a decentralized and directed network. In order to evaluate the quality of a fixed policy in this decentralized setting, one option is for agents to run decentralized temporal-difference (TD) collaboratively. To account for the practical scenarios where the state and action spaces are large and malicious attacks emerge, we focus on the decentralized TD learning with linear function approximation in the presence of malicious agents (often termed as Byzantine agents). We propose a trimmed mean-based Byzantine-resilient decentralized TD algorithm to perform policy evaluation in this setting. We establish the finite-time convergence rate, as well as the asymptotic learning error that depends on the number of Byzantine agents. Numerical experiments corroborate the robustness of the proposed algorithm.

Topics & Concepts

Robustness (evolution)Computer scienceReinforcement learningRate of convergenceByzantine architectureMathematical optimizationFunction (biology)LambdaConvergence (economics)MathematicsArtificial intelligenceComputer networkBiochemistryPhysicsBiologyOpticsEconomicsAncient historyChemistryChannel (broadcasting)Evolutionary biologyHistoryGeneEconomic growthDistributed Control Multi-Agent SystemsReinforcement Learning in RoboticsAdaptive Dynamic Programming Control
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