English

Coordinated Crawling via Reinforcement Learning

Biological Physics 2021-08-31 v2

Abstract

Rectilinear crawling locomotion is a primitive and common mode of locomotion in slender, soft-bodied animals. It requires coordinated contractions that propagate along a body that interacts frictionally with its environment. We propose a simple approach to understand how these coordinations arise in a neuromechanical model of a segmented, soft-bodied crawler via an iterative process that might have both biological antecedents and technological relevance. Using a simple reinforcement learning algorithm, we show that an initial all-to-all neural coupling converges to a simple nearest-neighbor neural wiring that allows the crawler to move forward using a localized wave of contraction that is qualitatively similar to what is observed in D. melanogaster larvae and used in many biomimetic solutions. The resulting solution is a function of how we weight gait regularization in the reward, with a tradeoff between speed and robustness to proprioceptive noise. Overall, our results, which embed the brain-body-environment triad in a learning scheme, has relevance for soft robotics while shedding light on the evolution and development of locomotion.

Keywords

Cite

@article{arxiv.2003.12845,
  title  = {Coordinated Crawling via Reinforcement Learning},
  author = {Shruti Mishra and Wim M. van Rees and L. Mahadevan},
  journal= {arXiv preprint arXiv:2003.12845},
  year   = {2021}
}
R2 v1 2026-06-23T14:30:23.438Z