Brake Motion Control for Quadruped Hopping Robot by Using Reference Height Control System


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Abstract


In this paper, the generation of brake motion control for our developed quadruped hopping robot while moving on two dimensional spaces by jumping continuously is discussed. The braking motion method which is approached is by applying the reference height control system to create the differences of front leg and back leg while making moving performance and correct the body posture which has inclined to make the quadruped hopping robot jump vertically while braking performances. On the other hand, this approached method can be used as the collision-avoidance behavior for the quadruped hopping robot. The MATLAB/Simulink model is used in order to conduct the pattern generation of quadruped hopping robot. As the result, effectiveness of approach method is confirmed to generate brake motion control of quadruped hopping robot while making continuous jumping vertically.
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Keywords


Quadruped Hopping Robot; CPG Networks; Moving and Braking Motion Control

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References


M.H Raibert; Legged Robot That Balance, MIT Press, Cambridge, Massachusetts, 1986

D. E. Koditscheck and M. Buhler: Analysis of a simplified hopping robot, Int. Journal of Robotics Res., Vol.10(6), pp. 587–605, 1991.

H. Kojima, I. Murakami, S. Yoshida, T. Sekiya: Development of Linear DC Motor surrounded by Four Faces for Hopping Robot and Experiments of Continuous Hopping, J. Robotics Soc. Japan, Vol.14(1), pp.91–95, 1994.(In Japanese)

H. Okubo, E. Nakano: General Knowledgement on Jumping type robot, J. Robotics Soc. Japan, Vol.11(3), pp. 342–347, 1998.(In Japanese)

R. Mellah, R. Toumi, Adaptive Neuro-fuzzy Control With Fast Learning Algorithm of PUMA560 Robot Manipulator, (2007) International Review of Mechanical Engineering (IREME), 1 (4), pp. 347 – 355.

H. Tsukagoshi, M. Sasaki, A. Kitagawa, T. Tanaka: Numerical Analysis and Design for Higher Jumping on Debris Using a Pneumatic Cylinder, Journal of The Society of Instrument and Control, Vol.40(8), pp. 859– 866, 2004.(In Japanese)

Jebelli, A., Yagoub, M.C.E., Abdul Rahim, R.H.J., Kazemi, H., Design and construction of an underwater robot based fuzzy logic controller, (2013) International Review of Mechanical Engineering (IREME), 7 (1), pp. 147-153.

Grillner S, Neurobiological Bases of Rhythmic Motor Acts Invertebrates, Science, Vol.228, pp.143-149, 1985.

William TL, Sigvardt KA, Kopell N, Ermentrout GB, Remler MP; Forcing of Coupled Nonlinear Oscillator: Studies of Intersegmental Coordination in the Lamprey Locomotor Central Pattern Generator, Journal of Neurophysiol, No.64(3), pp 862-871, 1990.

Bassler U; On the Definition of the Central Pattern Generator and its Sensory Control, Biol. Cybernatics, No.54, pp 65-69, 1986.

Marder E and Calabrese RL: Principles of rhythmic motor pattern production, Physiological Reviews, No. 76, pp 687–717, 1996.

M.S.M, Aras, S.S. Abdullah, A.A. Rahman, M.A.A.Aziz, "Thruster Modelling for Underwater Vehicle Using System Identification Method", International Journal Advance Robotic System, Vol.10, Issue 252, pp. 1-12, 2013.

G. Taga: A model of the neuro-musculo-skeletel system for human locomotion emergence of basic gait, Biol. Cybernetics, No.73,pp. 97–111, 1995.

G. Taga: A model of the neuro-musculo-skeletel system for human locomotion realtime adaptability under various constraints, Biol. Cybernetics, No.73, pp. 113–121, 1995.

H. Kimura: Dynamic walking on irregular terrain and running on flat terrain of the quadruped using neural oscillator, J. Robotics Soc. Jpn., Vol.16, No.8, pp. 1138–1145, 1998.

Y. Son, T. Kamano, T. Yasuno, T. Suzuki, and H. Harada: Generation of adaptive gait patterns for quadruped robot Using CPG Network, Electrical Eng. Jpn., Vol.115, No.1, pp. 35–43, 2006.

K. Kondo, T. Yasuno and H. Harada: Generaton of jumping motion patterns for quadruped hopping robot using CPG network, Journal of Signal Processing, Vol.11,No.11,pp. 321–324, 2007.

Bin Mohamed Kassim. A.; T. Yasuno "The Moving Control of Quadruped Hopping Robot Using Adaptive CPG Networks", 4th IEEE International Conference on Robotics, Automation and Mechatronics, Singapore, pp. 581-588, June 2010.

A.M. Kassim, N.H.A Rahim, M.F. Miskon, T.Yasuno “Moving Motion Control System On Developed Tripod Hopping Robot ”, Proceedings of International Conference on Electrical Control and Computer Engineering 2011,Kuantan, Malaysia,21-22 Jun 2011

N.H.A Rahim, A.M. Kassim, M.F. Miskon, A.H. Azahar, "Effectiveness of central pattern generator model on developed one legged hopping robot)", 2011 IEEE Student Conference on Research and Development (SCOReD, 85-88, 2011.

A.M. Kassim, N.H.A Rahim, M.F. Miskon, T.Yasuno “Effectiveness of Reference Height Control System for Tripod Hopping Robot”, Proceedings of 4th International Conference on Mechatronic 2011, Kuala Lumpur, Malaysia, 17-19 May 2011

A.M. Kassim, M. Z. A. Rashid, M. R. Yaacob, N. Abas, and T. Yasuno, “Effect of Reference Height Control System on CPG Networks for Quadruped Hopping Robot,” Trans Tech Publications Applied Mechanics and Materials, Switzerland, vol. 313–314, pp. 498-502, 2013.


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