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Improving Sample Complexity Bounds for (Natural) Actor-Critic Algorithms

Tengyu Xu, Zhe Wang, Yingbin Liang

2020Neural Information Processing Systems11 citations

Abstract

The actor-critic (AC) algorithm is a popular method to find an optimal policy in reinforcement learning. In the infinite horizon scenario, the finite-sample convergence rate for the AC and natural actor-critic (NAC) algorithms has been established recently, but under independent and identically distributed (i.i.d.) sampling and single-sample update at each iteration. In contrast, this paper characterizes the convergence rate and sample complexity of AC and NAC under Markovian sampling, with mini-batch data for each iteration, and with actor having general policy class approximation. We show that the overall sample complexity for a mini-batch AC to attain an $\epsilon$-accurate stationary point improves the best known sample complexity of AC by an order of $\mathcal{O}(\epsilon^{-1}\log(1/\epsilon))$, and the overall sample complexity for a mini-batch NAC to attain an $\epsilon$-accurate globally optimal point improves the existing sample complexity of NAC by an order of $\mathcal{O}(\epsilon^{-1}/\log(1/\epsilon))$. Moreover, the sample complexity of AC and NAC characterized in this work outperforms that of policy gradient (PG) and natural policy gradient (NPG) by a factor of $\mathcal{O}((1-\gamma)^{-3})$ and $\mathcal{O}((1-\gamma)^{-4}\epsilon^{-1}/\log(1/\epsilon))$, respectively. This is the first theoretical study establishing that AC and NAC attain orderwise performance improvement over PG and NPG under infinite horizon due to the incorporation of critic.

Topics & Concepts

Sample complexityIndependent and identically distributed random variablesAlgorithmConvergence (economics)Binary logarithmMathematicsReinforcement learningSample (material)Rate of convergenceOrder (exchange)Sampling (signal processing)Sample size determinationComputational complexity theoryDiscrete mathematicsCombinatoricsComputer scienceRandom variableStatisticsArtificial intelligencePhysicsKey (lock)ThermodynamicsComputer visionEconomic growthComputer securityEconomicsFilter (signal processing)FinanceReinforcement Learning in RoboticsAdaptive Dynamic Programming Control