Sage Journals: Discover world-class research

Abstract

Existing robots capable of hopping or running mostly rely on rigid actuators, but soft hopping or running robots based on muscle-like actuators have not yet been achieved. In this article, we report a tethered soft robot capable of hopping–running on smooth and rough surfaces with high speed. The hopping–running robot is composed of two soft joints that simulate the foreleg and hind leg driven by dielectric elastomer. The mass, length, width, and height of the robot are 6.5 g, 8.5 cm, 4.8 cm, and 50 cm, respectively. The robot can run at a speed of 51.83 cm/s (6.10 body lengths/s), which is much faster than previously reported locomotion robots driven by soft responsive materials. The robot also shows good adaptability to different terrains, such as marble, wood, rubber, sandpaper, and slopes. The robot can carry a load equal to its weight, can maintain a high locomotion speed, and demonstrates the potential ability to carry its power supply and control circuitry.

Get full access to this article

View all access options for this article.

References

Kovac

, Fuchs

, Guignard

, et al. A miniature 7g jumping robot. IEEE International Conference on Robotics and Automation, Pasadena, California,, 2008:373–378.

Loepfe

, Schumacher

, Lustenberger

, et al. An untethered, jumping roly-poly soft robot driven by combustion. Soft Robot, 2015; 2:33–41.

Haldane

, Plecnik

, Yim

, Fearing

. Robotic vertical jumping agility via series-elastic power modulation. Science Robot, 2016; 1:1–9.

Boston Dynamics. BigDog—The most advanced rough terrain robot on earth. http://bostondynamics.com/robot_bigdog.html (last accessed August 20, 2017).

Park

, Wensing

, Kim

. High-speed bounding with the MIT Cheetah 2: control design and experiments. Int J Robot Res, 2017; 36:027836491769424.

MIT Cheetah Robot Lands the Running Jump. http://cacm.acm.org/news/187932-mit-cheetah-robot-lands-the-running-jump (accessed Sept 1, 2019).

Seok

, Wang

, Meng

, et al. Design principles for highly efficient quadrupeds and implementation on the MIT Cheetah robot. IEEE International Conference on Robotics and Automation, Karlsruhe, Germany,, 2013:3307–3312.

Majidi

. Soft robotics: a perspective—current trends and prospects for the future. Soft Robot, 2014; 1:5–11.

Rus

, Tolley

. Design, fabrication and control of soft robots. Nature, 2015; 521:467–475.

10.

Henke

, Schlatter

, Anderson

. Soft dielectric elastomer oscillators driving bioinspired robots. Soft Robot, 2017; 4:353–366.

11.

Shintake

, Cacucciolo

, Shea

, Floreano

. Soft biomimetic fish robot made of dielectric elastomer actuators. Soft Robot, 2018; 5:1–9.

12.

Lee

, Lee

, Nam

, et al. Water uptake and migration effects of electroactive ion-exchange polymer metal composite (IPMC) actuator. Sens Actuators A Phys, 2005; 118:98–106.

13.

Firouzeh

, Ozmaeian

, Alasty

, et al. An IPMC-made deformable-ring-like robot. Smart Mater Struct, 2012; 21:65011–65021(11).

14.

Funakubo

, Kennedy

. Shape memory alloys. xii +275, 15 × 22 cm, Illustrated. New York: Gordon and Breach Science Publishers, 1987.

15.

Seok

, Onal

, Cho

, et al. Meshworm: a peristaltic soft robot with antagonistic nickel titanium coil actuators. IEEE/ASME Trans Mech, 2013; 18:1485–1497.

16.

Wang

, Desai

, Lee

. Light-controlled graphene-elastin composite hydrogel actuators. Nano Lett, 2013; 13:2826.

17.

Ionov

. Hydrogel-based actuators: possibilities and limitations. Mater Today, 2014; 17:494–503.

18.

Niiyama

, Nagakubo

, Kuniyoshi

. Mowgli: a bipedal jumping and landing robot with an artificial musculoskeletal system. IEEE International Conference on Robotics and Automation, Roma, Italy,, 2007:2546–2551.

19.

Tolley

, Shepherd

, Mosadegh

, et al. A resilient, untethered soft robot. Soft Robot, 2014; 1:213–223.

20.

Raibert

, Brown

Jr , Chepponis

. Experiments in balance with a 3D one-legged hopping machine. Int J Robot Res, 1984; 3:75–92.

21.

Pelrine

, Kornbluh

, Pei

, et al. High-speed electrically actuated elastomers with strain greater than 100%. Science, 2000; 287:836–839.

22.

Wingert

, Lichter

, Dubowsky

. On the design of large degree-of-freedom digital mechatronic devices based on bistable dielectric elastomer actuators. IEEE/ASME Trans Mech, 2006; 11:448–456.

23.

Karpelson

, Wei

G-Y

, Wood

. A review of actuation and power electronics options for flapping-wing robotic insects. IEEE International Conference on Robotics and Automation, Pasadena, California,, 2008:779–786.

24.

Godaba

, Li

, Wang

, et al. A soft jellyfish robot driven by a dielectric elastomer actuator. IEEE Robot Autom Lett, 2016; 1:624–631.

25.

, Chen

, Zou

, et al. A bio-inspired annelid robot: a dielectric elastomer actuated soft robot. Bioinspir Biomim, 2017; 12:025003.

26.

Zhao

, Niu

, McCoul

, et al. A rotary joint for a flapping wing actuated by dielectric elastomers: design and experiment. Meccanica, 2015; 50:2815–2824.

27.

, Li

, Liang

, et al. Fast-moving soft electronic fish. Sci Adv, 2017; 3:1602045.

28.

, Zou

, Zhao

, et al. Soft wall-climbing robots. Sci Robot, 2018; 3:eaat2874.

29.

Craigie

. Practical Anatomy of the Rabbit (Eighth Edition Fully Revised and Edited). Philadelphia, PA: The Blakiston Company,, 1948:198–206.

30.

Zhao

, Wang

, Xing

, et al. Equivalent dynamic model of DEMES rotary joint. Smart Mater Struct, 2016; 25:075025.

31.

Zhao

, Niu

, McCoul

, et al. Phenomena of nonlinear oscillation and special resonance of a dielectric elastomer minimum energy structure rotary joint. Appl Phys Lett, 2015; 106:133504.

32.

Pelrine

, Kornbluh

, Joseph

. Electrostriction of polymer dielectrics with compliant electrodes as a means of actuation. Sens Actuators A Phys, 1998; 64:77–85.

33.

Shepherd

, Ilievski

, Choi

, et al. Multigait soft robot. Proc Natl Acad Sci U S A, 2011; 108:20400.

34.

, Go

, Ko

, et al. Magnetic actuated pH-responsive hydrogel-based soft micro-robot for targeted drug delivery. Smart Mater Struct, 2016; 25:027001.

35.

, Chen

, Zou

, et al. Bio-inspired annelid robot: a dielectric elastomer actuated soft robot. Bioinspir Biomim, 2017; 12:025003.

36.

Pei

, Rosenthal

, Prahlad

, et al. Recent progress on electroelastomer artificial muscles and their application for biomimetic robots. Proceedings of SPIE, San Diego, California, 2004:5385.

37.

Jung

, Koo

, Nam

, et al. Artificial annelid robot driven by soft actuators. Bioinspir Biomim, 2007; 2:S42.

38.

Song

, Kim

, Rodrigue

, et al. Turtle mimetic soft robot with two swimming gaits. Bioinspir Biomim, 2016; 11:036010.

39.

Chang

, Kim

. Aquatic ionic-polymer-metal-composite insectile robot with multi-DOF legs. IEEE/ASME Trans Mech, 2013; 18:547–555.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

27.22 MB

0.07 MB

0.00 MB

Soft and Fast Hopping–Running Robot with Speed of Six Times Its Body Length Per Second

Abstract

Get full access to this article

References

Supplementary Material