Sage Journals: Discover world-class research

Abstract

A pneumatically-driven robot traverses surfaces with different traction by adopting an undulatory mode of locomotion. The robot is composed of soft elastomer (elastic modulus ~100 kPa), an inextensible but flexible neutral plane, and embedded pneumatic channels. In contrast to conventional robots and wheeled vehicles, the robot deforms elastically to make ground contact over a relatively large area, where interfacial tractions have a unique role in controlling both the speed and direction of locomotion. Here, we demonstrate that for the same undulatory gait, the robot will either move forward or backward depending on the ground composition. Building on mathematical principles of elasticity and friction, we introduce a theoretical model that identifies the tribological properties that determine the direction of locomotion. Though overlooked in the past, this tribology-controlled phenomenon represents a central feature of undulation on smooth, soft, and slippery surfaces. These insights provide a starting point for identifying locomotion strategies that allow soft robots, like their natural invertebrate counterparts, to navigate a broad range of surfaces and terrains.

Keywords

Soft robotics pneumatic actuation simulation inflation friction

Get full access to this article

View all access options for this article.

References

Alexandar

(2003) Principles of Animal Locomotion. Princeton: Princeton University Press, pp. 86–89.

Arena

Bonomo

Fortuna

. (2006) Design and control of an IPMC wormlike robot. IEEE Transactions on Systems, Man, and Cybernetics, Part B: Cybernetics 36(5): 1044–1052.

Berrigan

Pepin

(1995) How maggots move – allometry and kinematics of crawling in larval diptera. Journal of Insect Physiology 41(4): 329–337.

Casey

(1991) Energetics of caterpillar loco-motion – biomechanical constraints of a hydraulic skeleton. Science 252(5002): 112–114.

Cianchetti

Mattoli

Mazzolai

. (2009) A new design methodology of electrstrictive actuators for bio-inspired robotics. Sensors and Actuators B 142(1): 288–297.

Feinberg

Feigel

Shevkoplyas

. (2007) Muscular thin films for building actuators and powering devices. Science 317(5843): 1366–1370.

Garrey

Moore

(1915) Peristalsis and coordination in the earthworm. American Journal of Physiology 39(2): 139–148.

Gray

(1939) Studies in animal locomotion VIII. The kinetics of locomotion of Nereis diversicolor. Journal of Experimental Biology 16(1): 9–17.

Guo

Mahadevan

(2008) Limbless undulatory propulsion on land. Proceedings of the National Academy of Sciences USA (PNAS) 105: 3179–3184.

10.

Ilievski

Mazzeo

Shepherd

. (2011) Soft robotics for chemists. Angewandte Chemie 123(8): 1930–1935.

11.

Lin

Leisk

Trimmer

(2011) GoQBot: a caterpillar-inspired soft-bodied rolling robot. Bioinspiration and Biomimetics 6(2): 026007.

12.

Majidi

O’Reilly

Williams

(2012) On the stability of a rod adhering to a rigid surface: shear-induced stable adhesion and the instability of peeling. Journal of Mechanics and Physics of Solids 60: 827–843.

13.

Maladen

Ding

. (2009) Undulatory swimming in sand: subsurface locomotion of the sandfish lizard. Science 325: 314–318.

14.

Morin

Shepherd

Kwok

. (2012) Camouflage and display for soft machines. Science 337(6096): 828–832.

15.

Nawroth

Lee

Feinberg

. (2012) A tissue-engineered jellyfish with biomimetic propulsion. Nature Biotechnology 30(8): 792–797.

16.

Persson

BNJ

(2000) Sliding Friction: Physical Principles and Applications. Berlin: Springer, pp. 101–161.

17.

Qin

Xia

Whitesides

(2010) Soft lithography for micro- and nanoscale patterning. Nature Protocols 5(3): 491–502.

18.

Quake

Scherer

. (2000) From micro- to nanofabrication with soft materials. Science 290(5496): 1536–1540.

19.

Seok

Onal

Wood

. (2010) Peristaltic locomotion with antagonistic actuators in soft robotics. In: IEEE international conference on robotics and automation (ICRA), Anchorage, Alaska, USA, 3–8 May 2010, pp. 1228–1233.

20.

Shen

Sznitman

Krajacic

. (2012) Undulatory locomotion of Caenorhabditis elegans on wet surfaces. Biophysical Journal 102: 2772–2781.

21.

Shepherd

Ilievski

Choi

. (2011) Multigait soft robot. Proceedings of the National Academy of Sciences USA 108(51): 20400–20403.

22.

Suzumori

Iikura

Tanaka

. (1991) Development of flexible microactuator and its applications to robotic mechanisms. In: IEEE international conference on robotics and automation (ICRA), Sacramento, California, USA, April 1991, pp. 1622–1627.

23.

Suzumori

Endo

Kanda

. (2007) A bending pneumatic rubber actuator realizing soft-bodied manta swimming robot. In: IEEE international conference on robotics and automation (ICRA), Rome, Italy, April 2007, pp. 4975–4980.

24.

Xia

Whitesides

(1998) Soft lithography. Annual Review of Material Science 28: 153–184.

25.

Yeom

(2009) A biomimetic jellyfish robot based on ionic polymer metal comopsite actuators. Smart Materials and Structures 18(8): 085002.

26.

Yoshizawa

Chen

Israelachvili

(1993) Fundamental mechanisms of interfacial friction. 1. Relation between adhesion and friction. Journal of Physical Chemistry. 97: 4128–4140.

Influence of surface traction on soft robot undulation

Abstract

Keywords

Get full access to this article

References