PLoS Computational Biology (Oct 2018)

Modeling sensory-motor decisions in natural behavior.

  • Ruohan Zhang,
  • Shun Zhang,
  • Matthew H Tong,
  • Yuchen Cui,
  • Constantin A Rothkopf,
  • Dana H Ballard,
  • Mary M Hayhoe

DOI
https://doi.org/10.1371/journal.pcbi.1006518
Journal volume & issue
Vol. 14, no. 10
p. e1006518

Abstract

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Although a standard reinforcement learning model can capture many aspects of reward-seeking behaviors, it may not be practical for modeling human natural behaviors because of the richness of dynamic environments and limitations in cognitive resources. We propose a modular reinforcement learning model that addresses these factors. Based on this model, a modular inverse reinforcement learning algorithm is developed to estimate both the rewards and discount factors from human behavioral data, which allows predictions of human navigation behaviors in virtual reality with high accuracy across different subjects and with different tasks. Complex human navigation trajectories in novel environments can be reproduced by an artificial agent that is based on the modular model. This model provides a strategy for estimating the subjective value of actions and how they influence sensory-motor decisions in natural behavior.