Lifelike Pattern Generator for a Giant Quadrupedal Walking System Based on Fuzzy Logic

Lee, Sang-Won;Rim, Kyung-Hwa;Kwon, O-Hung;

doi:10.5302/J.ICROS.2012.18.2.133

Journal of Institute of Control, Robotics and Systems (제어로봇시스템학회논문지)

Volume 18 Issue 2
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Pages.133-140
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2012
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1976-5622(pISSN)
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2233-4335(eISSN)

Institute of Control, Robotics and Systems (제어로봇시스템학회)

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Lifelike Pattern Generator for a Giant Quadrupedal Walking System Based on Fuzzy Logic

퍼지로직 기반의 거대 4족 보행 시스템을 위한 실감형 패턴 발생기

Lee, Sang-Won (Korea Institute of Industrial Technology) ;
Rim, Kyung-Hwa (Korea University of Technology and Education) ;
Kwon, O-Hung (Korea Institute of Industrial Technology)

이상원 (한국생산기술연구원) ;
임경화 (한국기술교육대학교) ;
권오흥 (한국생산기술연구원)

Received : 2011.11.15
Accepted : 2011.12.20
Published : 2012.02.01

https://doi.org/10.5302/J.ICROS.2012.18.2.133 Citation PDF KSCI

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Abstract

In this paper, we suggest a lifelike pattern generator for a quadruped walking system with a head, a tail, four legs and a torso. The system looks like a giant dinosaur which stands over 7 meters tall with its legs over 2 meters long. We focus on its lifelike naturalness. Thus, generating logical patterns in harmony with head-body-tail patterns and quadrupedal locomotion patterns makes you feel that the quadruped walking system is alive. The basic patterns of four legs and a body are obtained from a 3D graphic animation, which is made and captured from various motions of similar species in existence since the giant dinosaurs are exterminated. The dinosaur-like mechanism also is designed from bone and joint structures of quadrupedal animals. The lifelike pattern generator based on fuzzy logic could generate lifelike motions according to the dinosaur-like mechanism and the basic patterns. A series of computer simulations and experimental implements show that the pattern generator makes the quadruped walking system lifelike.

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References

D. J. Tood, "Walking machines: an Introduction to legged robot," Kogan Page Ltd, 1985.
H. Cruse, "A quantitative model of walking incorporating central and peripheral infulences: 1. The control of individual leg," Biological Cydernetics, vol. 37, pp. 131-136.
J. A. Vilensky and J. A. Cook, "Do quadrupeds require a change in trunk posture to walk backward," Journal of Biomechanics, vol. 33, no. 8, pp. 911-916, 2000. https://doi.org/10.1016/S0021-9290(00)00071-3
M. Tokuriki, "Electromyographic and joint-mechanical studies in quadrupedal locomotion III. Gallop," Jap. J. vet. Sci., vol. 36, pp. 121-132, 1974. https://doi.org/10.1292/jvms1939.36.121
L. Favreau, L. Reveret, C. Depraz, and M.-P. Cani, Animal gaits from video. In SCA '04: Proceedings of the 2004 ACM SIGGRAPH/Eurographics symposium on Computer animation (Aire-la-Ville, Switzerland, Switzerland, 2004), Eurographics Association, pp. 277-286, 2004.
E. G. Conklin, Embryology and evolution; in: Mason, F., Creation by Evolution, Macmillan, New York, pp. 72-74, 1928.
S. W. Lee, J. Y. Kim, O. H. Kwon, D. H. Won, K. Y. Joung, "Development of the neck mechanism using parallel structure" KSPE 2011 Spring Conference (in Korean), pp. 377-378, 2011.
Sugar, Oscar, "Historical Perspective Coccyx: The Bone Named for a Bird," Spine 20 (3): pp. 379-383, Feb. 1995. https://doi.org/10.1097/00007632-199502000-00024
L. A. Zadeh, "A rationale for fuzzy control," in J. Dynamic Syst. Meas. Control, vol. 94, pp. 3-4, 1972. https://doi.org/10.1115/1.3426540