Optimization of two- and three-link snake-like locomotion

TL;DR

This paper analyzes and optimizes the efficiency of two- and three-link snake-like locomotion systems with anisotropic friction, identifying optimal friction coefficients and motion patterns through analytical and numerical methods.

Contribution

It introduces a comprehensive analysis and optimization of snake-like locomotion with multiple links, revealing optimal friction parameters and motion strategies for maximum efficiency.

Findings

Optimal backward and transverse friction coefficients enhance efficiency.

Maximum efficiency occurs at specific internal angle amplitudes.

Triangular paths in parameter space optimize three-link locomotion.

Abstract

We analyze two- and three-link planar snake-like locomotion and optimize the motion for efficiency. The locomoting system consists of two or three identical inextensible links connected via hinge joints, and the angles between the links are actuated as prescribed periodic functions of time. An essential feature of snake locomotion is frictional anisotropy: the forward, backward and transverse coefficients of friction are different. The dynamics are studied analytically and numerically for small and large amplitudes of the internal angles. Efficiency is defined as the ratio between distance traveled and the energy expended within one period, i.e. the inverse of the cost of locomotion. The optimal set of coefficients of friction to maximize efficiency consists of a large backward coefficient of friction and a small transverse coefficient of friction, compared to the forward coefficient of friction. For the two-link case with a symmetrical motion, efficiency is maximized when the internal angle amplitude is approximately $\pi/2$, for transverse coefficient sufficiently large. For the three-link case, the efficiency-maximizing paths are triangles in the parameter space of internal angles.