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6 - Evolution of rewards and learning mechanisms in Cyber Rodents

from Part III - Brain-based robots: architectures and approaches

Published online by Cambridge University Press:  05 February 2012

By
Eiji Uchibe  and
Kenji Doya
Edited by
Jeffrey L. Krichmar  and
Hiroaki Wagatsuma
Jeffrey L. Krichmar
Affiliation:
University of California, Irvine
Hiroaki Wagatsuma
Affiliation:
Kyushu Institute of Technology (KYUTECH), Japan
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Summary

Finding the design principle of reward functions is a big challenge in both artificial intelligence and neuroscience. Successful acquisition of a task usually requires rewards to be given not only for goals but also for intermediate states to promote effective exploration. We propose a method to design “intrinsic” rewards for autonomous robots by combining constrained policy gradient reinforcement learning and embodied evolution. To validate the method, we use the Cyber Rodent robots, in which collision avoidance, recharging from battery pack, and “mating” by software reproduction are three major “extrinsic” rewards. We show in hardware experiments that the robots can find appropriate intrinsic rewards for the visual properties of battery packs and potential mating partners to promote approach behaviors.

Introduction

In application of reinforcement learning (Sutton and Barto, 1998) to real-world problems, the design of the reward function is critical for successful achievement of the task. Designing appropriate reward functions is a nontrivial, time-consuming process in practical applications. Although it appears straightforward to assign positive rewards to desired goal states and negative rewards to states to be avoided, finding a good balance between multiple rewards often needs careful tuning. Furthermore, if rewards are given only at isolated goal states, blind exploration of the state space takes a long time. Rewards at intermediate subgoals, or even along the trajectories leading to the goal, promote focused exploration, but appropriate design of such additional rewards usually requires prior knowledge of the task or trial and error by the experimenter.

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Neuromorphic and Brain-Based Robots , pp. 109 - 128
Publisher: Cambridge University Press
Print publication year: 2011

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