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Abstract

In this article, we propose a soft eel robot design using soft pneumatic actuators that mimic eel muscles. Four pairs of soft actuators are used to construct the eel robot body. Pulse signals with suitable shifting phases are utilized to control delivery of compressed air to the actuators in sequence to create a sinusoidal wave from head to tail of the robot body. A model of hydrodynamic forces acting on an anguilliform swimmer when moving in fluid was built to estimate the thrust force generated by the robot at different tail beat frequencies. Experimental data revealed that the generated thrust force was positively correlated with the beat frequency. Measured data showed that swimming efficiency depended on both generated thrust force and body posture in situ. At the beat frequency of 1.25 Hz, and air pressure at three segments from head to tail of 65, 50, and 30 kPa, respectively, the eel robot body showed the best cost of transport (COT) of 19.21 with velocity of 10.5 cm/s (or 0.198 body length per second [BL/s]), compared to the other's values of operation frequency and air pressure. We also found that control shifting phase strongly affects the swimming speed and COT. The robot body reached the highest velocity at around 19 cm/s (0.36 BL/s) with the COT of 10.72. Obtained result in this research would contribute to development of soft elongated swimming robot and enhance the knowledge on swimming performance of both robot and natural eels.

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References

Clapham

, Hu

. iSplash-II: Realizing fast carangiform swimming to outperform a real fish. International Conference on Intelligent Robots and Systems (IROS2014), Illinois, September 14–18,, 2014; 1080–1086.

Manfredi

, Assaf

, Mintchev

, et al. A bioinspired autonomous swimming robot as a tool for studying goal-directed locomotion. Biol Cybern, 2013; 107:513–527.

Ayers

, Wilbur

, Olcott

Lamprey robots. The 1st International Symposium on Aqua Biomechanisms, Tokai International University, Honolulu, Hawaii, USA, 2000.

Curet

, Patankar

, Lauder

, et al. Aquatic manoeuvering with counter-propagating waves: a novel locomotive strategy. J R Soc Interface, 2011; 8:1041–1050.

Katzschmann

, DelPreto

, MacCurdy

, et al. Exploration of underwater life with an acoustically controlled soft robotic fish. Sci Robot, 2018; 3:eaar3449.

Donatelli

, Bradner

, Mathews

, et al. Prototype of a fish inspired swimming silk robot. IEEE International Conference on Soft Robotics, Livorno, Italy, April 24–28,, 2018; 60–65.

Marchese

, Onal

, Rus

. Autonomous soft robotic fish capable of escape maneuvers using fluidic elastomer actuators. Soft Robot, 2014; 1:233–250.

Frame

, Lopez

, Curet

, et al. Thrust force characterization of free-swimming soft robotic jellyfish. Bioinspir Biomim, 2018; 13:064001.

Hou

, Yang

, Su

, et al. Design and experiments of a squid-like aquatic-aerial vehicle with soft morphing fins and arms. International Conference on Robotics and Automation 2019, Montreal, Canada, May 20–24,, 2019; 4681–4687.

10.

Aubin

, Choudhury

, Jerch

, et al. Electrolytic vascular systems for energy-dense robots. Nature, 2019; 571:51–57.

11.

Christianson

, Goldberg

, Deheyn

, et al. Translucent soft robots driven by frameless fluid electrode dielectric elastomer actuators. Sci Robot, 2018; 3:eaat1893.

12.

Feng

, Sun

, Todd

, et al. Body wave generation for anguilliform locomotion using a fiber-reinforced soft fluidic elastomer actuator array toward the development of the eel-inspired underwater soft robot. Soft Robot, 2020; 7:233–250.

13.

Sfakiotakis

, Lane

, Davies

JBC

. Review of fish swimming modes for aquatic locomotion. IEEE J Oceanic Eng, 1999; 24:237252.

14.

Magnuson

JJ.

Locomotion by scombrid fishes: hydromechanics, morphology and behavior. Fish Physiol, 1978; 7:239313.

15.

Gemmell

, Fogerson

, Costello

, et al. How the bending kinematics of swimming lampreys build negative pressure fields for suction thrust. J Exp Biol, 2016; 219:3884–3895.

16.

Tytell

, Lauder

. The hydrodynamic of eel swimming: I. Wake structure. J Exp Biol, 2004; 207:1825–1841.

17.

Webb

PW.

Form and function in fish swimming. Sci Am, 1984; 251:164–174.

18.

Gemmell

, Costello

, Colin

, et al. Passive energy recapture in jellyfish contributes to propulsive advantage over other metazoans. Proc Natl Acad Sci U S A, 2013; 110:17904–17909.

19.

Odor

, Stewart

, Gilly

, et al. Squid rocket science: how squid launch into air. Deep Sea Res Part II Top Stud Oceanogr, 2013; 95:113–118.

20.

Westphal

, Rulkov

, Ayers

, et al. Controlling a lamprey-based robot with an electronic nervous system. Smart Struct Syst, 2011; 8:39–52.

21.

Low

, Yang

, Pattathil

, et al. Initial prototype design and investigation of an undulating body by SMA. International Conference on Automation Science and Engineering, Shanghai, China, October 7–10,, 2006; 472–477.

22.

Ijspeert

, Crespi

Online trajectory generation in an amphibious snake robot using a lamprey-like central pattern generator model. IEEE International Conference on Robotics and Automation (ICRA), pp. 262–268, Roma, Italy, April 10–14, 2007.

23.

Crespi

, Karakasiliotis

, Guignard

, et al. Salamandra Robotica II: an amphibious robot to study salamander-like swimming and walking gaits. IEEE Trans Rob Autom, 2013; 29:308320.

24.

Chen

, Jiang

. Swimming performance of a tensegrity robotic fish. Soft Robot, 2019; 6:520–531.

25.

Zhong

, Li

, Du

. A novel robot fish with wire-driven active body and compliant tail. IEEE ASME Trans Mechatron, 2017; 22:16331643.

26.

Shintake

, Cacucciolo

, Shea

, et al. Soft biomimetic fish robot made of dielectric elastomer actuators. Soft Robot, 2018; 5:466–474.

27.

Katzschmann

, Marchese

, Rus

Hydraulic autonomous soft robotic fish for 3D swimming. Conference on International Symposium on Experimental Robotics, Vol. 14, pp. 405–420, Marrakech and Essaouira, Morocco, June 15–18, 2014.

28.

Vorus

, Taravella

. Anguilliform fish propulsion of highest hydrodynamic efficiency. J Mar Sci Appl, 2011; 10, Article number 163:163–174.

29.

Sfakiotakis

, Lane

, Davies

JBC

. Review of fish swimming modes for aquatic locomotion. IEEE J Ocean Eng, 1999; 24:237–252.

30.

Cengel

, Cimbala

. Fluid Mechanics: Fundamentals and Application. McGraw-Hill, Penn Plaza, NY, USA, 2010.

31.

Pineirua

, Godoy-Diana

, Thiria

. Resistive thrust production can be as crucial as added mass mechanisms for inertial undulatory swimmers. Phys Rev, 2015; 92:021001.

32.

Nguyen

, Ho

. Kinematic evaluation of a series of soft actuators in designing an eel-inspired robot. 2020 IEEE/SICE International Symposium on System Intergration (SII), January 12–15, 2020, Honolulu, Hawaii.

33.

Onal

, Rus

. A modular approach to soft robots. The Fourth IEEE RAS/EMBS International Conference on Biomedical and Biomechatronics, Rome, Italy, June 24–27,, 2012; 1038–1045.

34.

Ramananarivo

, Godoy-Diana

, Thiria

. Passive elastic mechanism to mimic fish-muscle action in anguilliform swimming. J R Soc Interface, 2013; 10:20130667.

35.

Quinn

, Lauder

, Smits

. Maximizing the efficiency of a flexible propulsor using experimental optimization. J Fluid Mech, 2015; 767:430–448.

36.

Barrett

, Triantafyllou

, Yue

DKP

, et al. Drag reduction in fish-like locomotion. J Fluid Mech, 1999; 392:183–212.

37.

Di Santo

, Kenaley

, Lauder

. High postural costs and anaerobic metabolism during swimming support the hypothesis of a U-shaped metabolismspeed curve in fishes. Proc Natl Acad Sci U S A, 2017; 114:13048–13053.

38.

Zhu

, White

, Wainwright

, et al. Tuna robotics: a high-frequency experimental platform exploring the performance space of swimming fishes. Sci Robot, 2019; 4:eaax4615.

39.

Tytell

ED.

The hydrodynamic of eel swimming: II. Effect of swimming speed. J Exp Biol, 2004; 207:3265–3279.

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Anguilliform Swimming Performance of an Eel-Inspired Soft Robot

Abstract

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