Computational Rationalization: The Inverse Equilibrium Problem
Abstract
Modeling the purposeful behavior of imperfect agents from a small number of observations is a challenging task. When restricted to the single-agent decision-theoretic setting, inverse optimal control techniques assume that observed behavior is an approximately optimal solution to an unknown decision problem. These techniques learn a utility function that explains the example behavior and can then be used to accurately predict or imitate future behavior in similar observed or unobserved situations. In this work, we consider similar tasks in competitive and cooperative multi-agent domains. Here, unlike single-agent settings, a player cannot myopically maximize its reward --- it must speculate on how the other agents may act to influence the game's outcome. Employing the game-theoretic notion of regret and the principle of maximum entropy, we introduce a technique for predicting and generalizing behavior, as well as recovering a reward function in these domains.
BibTeX
@conference{Waugh-2011-7302,author = {Kevin Waugh and Brian D. Ziebart and J. Andrew (Drew) Bagnell},
title = {Computational Rationalization: The Inverse Equilibrium Problem},
booktitle = {Proceedings of (ICML) International Conference on Machine Learning},
year = {2011},
month = {June},
pages = {1169 - 1176},
keywords = {Game Theory, Inverse Optimal Control, Artificial Intelligence},
}