Design and Modeling of a New Drive System and Exaggerated Rectilinear-Gait for a Snake-Inspired Robot

Author:

Hopkins James K.1,Gupta Satyandra K.2

Affiliation:

1. Department of Mechanical Engineering, University of Maryland, College Park, MD 20742

2. Department of Mechanical Engineering and Institute for Systems Research, University of Maryland, College Park, MD 20742 e-mail:

Abstract

In recent years, snake-inspired locomotion has garnered increasing interest in the bio-inspired robotics community. This positive trend is largely due to the unique and highly effective gaits utilized by snakes to traverse various terrains and obstacles. These gaits make use of a snake's hyper-redundant body structure to adapt to the terrain and maneuver through tight spaces. Snake-inspired robots utilizing rectilinear motion, one of the primary gaits observed in natural snakes, have demonstrated favorable results on various terrains. However, previous robot designs utilizing rectilinear gaits were slow in speed. This paper presents a design and an exaggerated rectilinear gait concept for a snake-inspired robot which overcomes this limitation. The robot concept incorporates high speed linear motion and a new multimaterial, variable friction force anchoring concept. A series of traction experiments are conducted to determine appropriate materials to be used in the friction anchor (FA) design. The gait concept includes four unique gaits: a forward and a turning gait, which both emphasize speed for the robot; and a forward and turning gait which emphasize traction. We also report a comparative study of the performance of prototype robot designed using these concepts to other published snake-inspired robot designs.

Publisher

ASME International

Subject

Mechanical Engineering

Reference38 articles.

1. The Mechanism of Locomotion in Snakes;J. Exp. Biol.,1946

2. Rectilinear Motion in a Snake (Boa Occidentalis);J. Exp. Biol.,1950

3. A Survey of Snake-Inspired Robot Designs;Bioinspiration Biomimetics,2009

4. A Survey on Snake Robot Modeling and Locomotion;Robotica,2009

5. Effect of Friction Models on Snake Robot Performance;Int. J. Model. Optim.,2011

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