Geometric Mechanics for Continuous Swimmers on Granular Material - Robotics Institute Carnegie Mellon University

Geometric Mechanics for Continuous Swimmers on Granular Material

Jin Dai, Hossein Faraji, Perrin Schiebel, Chaohui Gong, Matthew Travers, Ross Hatton, Daniel Goldman, and Howie Choset
Conference Paper, Proceedings of APS March Meeting, March, 2016

Abstract

Animal experiments have shown that Chionactis occipitalis(N =10) effectively undulating on granular substrates exhibits a particular set of waveforms which can be approximated by a sinusoidal variation in curvature, i.e., a serpenoid wave. Furthermore, all snakes tested used a narrow subset of all available waveform parameters, measured as the relative curvature equal to 5.0+/-0.3, and number of waves on the body equal to1.8+/-0.1. We hypothesize that the serpenoid wave of a particular choice of parameters offers distinct benefit for locomotion on granular material. To test this hypothesis, we used a physical model (snake robot) to empirically explore the space of serpenoid motions, which is linearly spanned with two independent continuous serpenoid basis functions. The empirically derived height function map, which is a geometric mechanics tool for analyzing movements of cyclic gaits, showed that displacement per gait cycle increases with amplitude at small amplitudes, but reaches a peak value of 0.55 body-lengths at relative curvature equal to 6.0. This work signifies that with shape basis functions, geometric mechanics tools can be extended for continuous swimmers.

BibTeX

@conference{Dai-2016-122404,
author = {Jin Dai and Hossein Faraji and Perrin Schiebel and Chaohui Gong and Matthew Travers and Ross Hatton and Daniel Goldman and Howie Choset},
title = {Geometric Mechanics for Continuous Swimmers on Granular Material},
booktitle = {Proceedings of APS March Meeting},
year = {2016},
month = {March},
}