1. Enriching behavioral ecology with reinforcement learning methods
- Author
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Andrew G. Barto, Karthik Panchanathan, and Willem E. Frankenhuis
- Subjects
0106 biological sciences ,0301 basic medicine ,Evolution ,Computer science ,Development ,Dynamic programming ,Social Development ,010603 evolutionary biology ,01 natural sciences ,03 medical and health sciences ,Behavioral Neuroscience ,Reward system ,Reward ,Reinforcement learning ,Animals ,Humans ,Learning ,Adaptation ,Selection, Genetic ,Set (psychology) ,Adaptation (computer science) ,Selection (genetic algorithm) ,Cognitive science ,Behavior ,Behavior, Animal ,Ecology ,General Medicine ,Decision problem ,Adaptation, Physiological ,Biological Evolution ,Variety (cybernetics) ,Phenotype ,030104 developmental biology ,Animal Science and Zoology ,Reinforcement, Psychology ,Adaptive behavior (ecology) - Abstract
Contains fulltext : 201963.pdf (Publisher’s version ) (Open Access) This article focuses on the division of labor between evolution and development in solving sequential, state-dependent decision problems. Currently, behavioral ecologists tend to use dynamic programming methods to study such problems. These methods are successful at predicting animal behavior in a variety of contexts. However, they depend on a distinct set of assumptions. Here, we argue that behavioral ecology will benefit from drawing more than it currently does on a complementary collection of tools, called reinforcement learning methods. These methods allow for the study of behavior in highly complex environments, which conventional dynamic programming methods do not feasibly address. In addition, reinforcement learning methods are well-suited to studying how biological mechanisms solve developmental and learning problems. For instance, we can use them to study simple rules that perform well in complex environments. Or to investigate under what conditions natural selection favors fixed, non-plastic traits (which do not vary across individuals), cue-driven-switch plasticity (innate instructions for adaptive behavioral development based on experience), or developmental selection (the incremental acquisition of adaptive behavior based on experience). If natural selection favors developmental selection, which includes learning from environmental feedback, we can also make predictions about the design of reward systems. Our paper is written in an accessible manner and for a broad audience, though we believe some novel insights can be drawn from our discussion. We hope our paper will help advance the emerging bridge connecting the fields of behavioral ecology and reinforcement learning. 7 p.
- Published
- 2019