Characterizing Reinforcement Learning Methods through Parameterized Learning Problems

Abstract

The field of reinforcement learning (RL) has been energized in the past few decades by elegant theoretical results indicating under what conditions, and how quickly, certain algorithms are guaranteed to converge to optimal policies. However, in practical problems, these conditions are seldom met. When we cannot achieve optimality, the performance of RL algorithms must be measured empirically. Consequently, in order to meaningfully differentiate learning methods, it becomes necessary to characterize their performance on different problems, taking into account factors such as state estimation, exploration, function approximation, and constraints on computation and memory. To this end, we propose parameterized learning problems, in which such factors can be controlled systematically and their effects on learning methods characterized through targeted studies. Apart from providing very precise control of the parameters that affect learning, our parameterized learning problems enable benchmarking against optimal behavior; their relatively small sizes facilitate extensive experimentation. Based on a survey of existing RL applications, in this article, we focus our attention on two predominant, first order factors: partial observability and function approximation. We design an appropriate parameterized learning problem, through which we compare two qualitatively distinct classes of algorithms: on-line value function-based methods and policy search methods. Empirical comparisons among various methods within each of these classes project Sarsa() and Q-learning() as winners among the former, and CMA-ES as the winner in the latter. Comparing Sarsa() and CMA-ES further on relevant problem instances, our study highlights regions of the problem space favoring their contrasting approaches. Short run-times for our experiments allow for an extensive search procedure that provides additional insights on relationships between method-specific parameterssuch as eligibility traces.

Open PDF

Document Details

Document Type
Technical Report
Publication Date
Jun 03, 2011
Accession Number
AD1024580

Entities

People

  • Peter Stone
  • Shivaram Kalyanakrishnan

Organizations

  • University of Texas at Austin

Tags

Communities of Interest

  • Autonomy

DTIC Thesaurus Topics

  • Algorithms
  • Artificial Intelligence
  • Bayesian Networks
  • Computational Science
  • Computer Programming
  • Evolutionary Algorithms
  • Information Processing
  • Information Science
  • Information Systems
  • Machine Learning
  • Multiagent Systems
  • Network Science
  • Neural Networks
  • Operations Research
  • Particle Swarm Optimization
  • Reinforcement Learning
  • Supervised Machine Learning

Fields of Study

  • Computer science

Readers

  • Adaptive Control and Estimation with Uncertainty in Dynamic Systems.
  • Computational Modeling and Simulation
  • Neural Network Machine Learning.

Technology Areas

  • AI & ML
  • AI & ML - Machine Learning Algorithms
  • Space
  • Space - Spacecraft Maneuvers