From animals to jumping robots: A teaching experience on bioinspired robotics

Abstract

This work describes a teaching experience in bioinspired robotics, in which students were asked to design jumping robots inspired by animals. This bioinspired robotics course is offered to Master’s students in mechanical engineering with the aim of teaching them how to improve the efficiency and maneuverability of robots by drawing inspiration from biological locomotion strategies and enhancing their creativity through a bioinspired approach. This class emphasized translating biological principles into useful robots, and students based their designs upon locusts and Salticidae, two very effective species in their energy use. The students focused on mechanical design, energy storage and release approaches, and control strategies. The resulting prototypes emphasize that bioinspired solutions can offer effective strategies for robust and dynamic locomotion in robotics. In addition, it demonstrates the importance of bioinspired projects and how they can provide students with the interdisciplinary foundation needed to work in biology, mechanics, and robotics.

Keywords

Robot design bioinspired robotics jumping robots group project

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References

Vandevenne

Verhaegen

Dewulf

, et al. A scalable approach for ideation in biologically inspired design. Artif Intell Eng Des Anal Manuf 2015; 29: 19–31.

Rowland

. Biomimicry step-by-step. Bioins Biomimet Nanobiomat 2017; 6: 102–112.

Mazzolai

Laschi

. A vision for future bioinspired and biohybrid robots. Sci Robot 2020; 5: eaba6893.

Nagel

Pittman

Pidaparti

, et al. Teaching bioinspired design using c–k theory. Bioinsp Biomimet Nanobiomater 2017; 6: 77–86.

Cayetano-Jiménez

Bustamante-Bello

Ramírez-Cadena

. Bridging the gap: bioinspired robotics as catalyst for interdisciplinary education. Front Educ 2024; 9: 1375487.

Bernstein

Puttic

Wendell

, et al. Designing biomimetic robots: iterative development of an integrated technology design curriculum. Educ Technol Res Dev 2022; 70: 119–147.

Garofalo

Sandler

Seth

. Evaluation of a snake jaw robot to teach integrated biology, mathematics, and engineering. In: 2020 IEEE integrated stem education conference (ISEC), 2020, pp.1–8. DOI: 10.1109/ISEC49744.2020.9280695.

Moore

Ehsan

Kim

, et al. Creating biologically inspired design units for high school engineering courses. In: 2021 IEEE frontiers in education conference (FIE), 2021, pp.1–4. DOI: 10.1109/FIE49875.2021.9637238.

Cattano

Nikou

Klotz

. Teaching systems thinking and biomimicry to civil engineering students. J Profess Issues Eng Educ Pract 2011; 137: 176–182.

10.

Nelson

Wilson

Yen

. A study of biologically-inspired design as a context for enhancing student innovation. In: 2009 39th IEEE frontiers in education conference, 2009, pp.1–5. DOI: 10.1109/FIE.2009.5350871.

11.

Bruck

Gershon

Golden

, et al. Training mechanical engineering students to utilize biological inspiration during product development. Bioinspir Biomim 2007; 2: 198–209.

12.

Yen

Weissburg

Helms

, et al. Biologically Inspired Design: A Tool for Interdisciplinary Education chapter 10. Boca Raton, FL, U.S.A.: CRC Press Taylor & Francis Group, 2012. pp. 331–360. DOI: 10.1109/ISEC49744.2020.9280695.

13.

Zhang

Zhao

Chen

, et al. A survey of bioinspired jumping robot: Takeoff, air posture adjustment, and landing buffer. Appl Bionics Biomech 2017; 2017: 4780160.

14.

Zhang

Zou

, et al. Biologically inspired jumping robots: A comprehensive review. Rob Auton Syst 2020; 124: 103362.

15.

Scott

. The locust jump: an integrated laboratory investigation. Adv Physiol Educ 2005; 29: 21–26.

16.

Cofer

Cymbalyuk

Heitler

, et al. Neuromechanical simulation of the locust jump. J Exp Biol 2010; 213: 1060–1068.

17.

Heitler

Burrows

. the locust jump. I. The motor programme. J Exp Biol 1977; 66: 203–219.

18.

Santer

Yamawaki

Rind

, et al. Motor activity and trajectory control during escape jumping in the locust locusta migratoria. J Compar Physiol A 2005; 191: 965–975.

19.

Sutton

Burrows

. The mechanics of elevation control in locust jumping. J Compar Physiol A 2008; 194: 557–563.

20.

Zaitsev

Gvirsman

Hanan

, et al. A locust-inspired miniature jumping robot. Bioinspir Biomim 2015; 10: 066012.

21.

Ren

, et al. Locust-inspired jumping mechanism design and improvement based on takeoff stability. J Mech Robot 2023; 16: 061013.

22.

Yang

Feng

, et al. The continuous jump control of a locust-inspired robot with omnidirectional trajectory adjustment. IEEE Robot Autom Lett 2024; 9: 2040–2047.

23.

Zhang

Song

, et al. A bio-inspired jumping robot: Modeling, simulation, design, and experimental results. Mechatronics 2013; 23: 1123–1140.

24.

Zhang

Peng

, et al. A locust-inspired robot capable of continuous crawl–jump–gliding locomotion with optimized transitional control. IEEE Trans Robot 2025; 41: 220–235.

25.

Jin

Zhang

, et al. Design and optimization of a miniature locust-inspired stable jumping robot. IEEE Robot Autom Lett 2023; 8: 4673–4680.

26.

Zhang

Yang

Zhao

, et al. Kinematic synthesis method for the one-degree-of-freedom jumping leg mechanism of a locust-inspired robot. Sci China Technol Sci 2020; 63: 472–487.

27.

Tsai

Wang

, et al. Miniature soft jumping robots made by additive manufacturing. Smart Mater Struct 2023; 32: 105022.

28.

Hill

. Targeted jumps by salticid spiders (araneae, salticidae, phidippus). Peckhamia E-publication 2006; 9: 1–28.

29.

Hill

. The jumping behavior of jumping spiders: a review (araneae: Salticidae)1. Peckhamia E-publication 2018; 167: 1–28.

30.

Göttler

Elflein

Siegwart

, et al. Spider origami: Folding principle of jumping spider leg joints for bioinspired fluidic actuators. Adv Sci 2021; 8: 2003890.

31.

Faraji

Tachella

Hatton

. Aiming and vaulting: Spider inspired leaping for jumping robots. In: 2016 IEEE International conference on robotics and automation (ICRA), 2016, pp.2082–2087. DOI: 10.1109/ICRA.2016.7487357.

32.

Spröwitz

Gottler

Sinha

, et al. Scalable pneumatic and tendon driven robotic joint inspired by jumping spiders. In: 2017 IEEE international conference on robotics and automation (ICRA), 2017, pp.64–70.

33.

Gavriloski

Jovanova

Tasevski

, et al. Development of new air spring dynamic model. FME Trans 2014; 42: 305–310.

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