Abstract
Fish swim by undulating their bodies. These propulsive motions require coordinated shape changes of a body that interacts with its fluid environment, but the specific shape coordination that leads to robust turning and swimming motions remains unclear. To address the problem of underwater motion planning, we propose a simple model of a three-link fish swimming in a potential flow environment and we use model-free reinforcement learning for shape control. We arrive at optimal shape changes for two swimming tasks: swimming in a desired direction and swimming towards a known target. This fish model belongs to a class of problems in geometric mechanics, known as driftless dynamical systems, which allow us to analyze the swimming behavior in terms of geometric phases over the shape space of the fish. These geometric methods are less intuitive in the presence of drift. Here, we use the shape space analysis as a tool for assessing, visualizing, and interpreting the control policies obtained via reinforcement learning in the absence of drift. We then examine the robustness of these policies to drift-related perturbations. Although the fish has no direct control over the drift itself, it learns to take advantage of the presence of moderate drift to reach its target.
1 More- Received 8 August 2020
- Accepted 15 March 2021
- Corrected 13 May 2021
DOI:https://doi.org/10.1103/PhysRevFluids.6.050505
©2021 American Physical Society
Physics Subject Headings (PhySH)
Corrections
13 May 2021
Correction: The previously published order of authors was presented incorrectly and has been fixed, and the affiliations are now identified by superscript numbers.
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Machine Learning in Fluid Mechanics Invited Papers
Physical Review Fluids publishes a collection of invited papers which advance the use of machine learning in fluid mechanics.