Design, analysis, and neural control of a bionic parallel mechanism

Yaguang ZHU; Shuangjie ZHOU; Manoonpong PORAMATE; Ruyue LI‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬

doi:10.1007/s11465-021-0640-8

Front. Mech. Eng. ›› 2021, Vol. 16 ›› Issue (3) : 468 -486. DOI: 10.1007/s11465-021-0640-8

RESEARCH ARTICLE

Design, analysis, and neural control of a bionic parallel mechanism

Yaguang ZHU ¹^,²^,³^,^†
, Shuangjie ZHOU ¹
, Manoonpong PORAMATE ³^,⁴
, Ruyue LI‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬ ¹

Author information +

History +

PDF (4176KB)

Abstract

Although the torso plays an important role in the movement coordination and versatile locomotion of mammals, the structural design and neuromechanical control of a bionic torso have not been fully addressed. In this paper, a parallel mechanism is designed as a bionic torso to improve the agility, coordination, and diversity of robot locomotion. The mechanism consists of 6-degree of freedom actuated parallel joints and can perfectly simulate the bending and stretching of an animal’s torso during walking and running. The overall spatial motion performance of the parallel mechanism is improved by optimizing the structural parameters. Based on this structure, the rhythmic motion of the parallel mechanism is obtained by supporting state analysis. The neural control of the parallel mechanism is realized by constructing a neuromechanical network, which merges the rhythmic signals of the legs and generates the locomotion of the bionic parallel mechanism for different motion patterns. Experimental results show that the complete integrated system can be controlled in real time to achieve proper limb–torso coordination. This coordination enables several different motions with effectiveness and good performance.

Graphical abstract

Keywords

neural control / behavior network / rhythm / motion pattern

Cite this article

Download citation ▾

Yaguang ZHU, Shuangjie ZHOU, Manoonpong PORAMATE, Ruyue LI‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬. Design, analysis, and neural control of a bionic parallel mechanism. Front. Mech. Eng., 2021, 16(3): 468-486 DOI:10.1007/s11465-021-0640-8

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Ananthanarayanan A, Azadi M, Kim S. Towards a bio-inspired leg design for high-speed running. Bioinspiration & Biomimetics, 2012, 7(4): 046005

[2]	Gehring C, Coros S, Hutler M, . Practice makes perfect: An optimization-based approach to controlling agile motions for a quadruped robot. IEEE Robotics & Automation Magazine, 2016, 23(1): 34–43

[3]	Manoonpong P, Parlitz U, Wörgötter F. Neural control and adaptive neural forward models for insect-like, energy-efficient, and adaptable locomotion of walking machines. Frontiers in Neural Circuits, 2013, 7: 12

[4]	Schilling N, Hackert R. Sagittal spine movements of small therian mammals during asymmetrical gaits. Journal of Experimental Biology, 2006, 209(19): 3925–3939

[5]	Deng Q, Wang S, Xu W, . Quasi passive bounding of a quadruped model with articulated spine. Mechanism and Machine Theory, 2012, 52: 232–242

[6]	Hildebrand M. Motions of the running cheetah and horse. Journal of Mammalogy, 1959, 40(4): 481–495

[7]	Galis F, Carrier D R, van Alphen J, . Fast running restricts evolutionary change of the vertebral column in mammals. Proceedings of the National Academy of Sciences of the United States of America, 2014, 111(31): 11401–11406

[8]	Albiez J, Luksch T, Berns K, . A behaviour network concept for controlling walking machines. In: Kimura H, Tsuchiya K, Ishiguro A, et al., eds. Adaptive Motion of Animals and Machines. 1st ed. Tokyo: Springer, 2006, 237–246

[9]	Khoramshahi M, Spröwitz A, Tuleu A, . Benefits of an active spine supported bounding locomotion with a small compliant quadruped robot. In: Proceedings of 2013 IEEE International Conference on Robotics and Automation. Karlsruhe: IEEE, 2013, 3329–3334

[10]	Kuehn D, Beinersdorf F, Bernhard F, . Active spine and feet with increased sensing capabilities for walking robots. In: Proceedings of International Symposium on Artificial Intelligence, Robotics and Automation in Space. Karlsruhe: i-SAIRAS, 2012

[11]	Takuma T, Ikeda M, Masuda T. Facilitating multi-modal locomotion in a quadruped robot utilizing passive oscillation of the spine structure. In: Proceedings of 2010 IEEE/RSJ International Conference on Intelligent Robots and Systems. Taipei: IEEE, 2010, 4940–4945

[12]	Haynes G C, Pusey J, Knopf R, . Laboratory on legs: An architecture for adjustable morphology with legged robots. Proceedings of SPIE: Unmanned Systems Technology XIV, 2012, 8387: 786–796

[13]	Seok S, Wang A, Chuah M Y, . Design principles for highly efficient quadrupeds and implementation on the MIT Cheetah robot. In: Proceedings of 2013 IEEE International Conference on Robotics and Automation. Karlsruhe: IEEE, 2013, 3307–3312

[14]	Zhao Q, Ellenberger B, Sumioka H, . The effect of spine actuation and stiffness on a pneumatically-driven quadruped robot for cheetah-like locomotion. In: Proceedings of 2013 IEEE International Conference on Robotics and Biomimetics (ROBIO). Shenzhen: IEEE, 2013, 1807–1812

[15]	Khosravi M A, Taghirad H D. Robust PID control of fully-constrained cable driven parallel robots. Mechatronics, 2014, 24(2): 87–97

[16]	Zhao J, Wang P, Yang T, . Design of a novel modal space sliding mode controller for electro-hydraulic driven multi-dimensional force loading parallel mechanism. Instrument Society of America Transaction, 2020, 99: 374–386

[17]	Ghasemi J, Moradinezhad R, Hosseini M A. Kinematic synthesis of parallel manipulator via neural network approach. International Journal of Engineering, 2019, 30(9): 1319–1325

[18]	Xu J, Du Y, Chen Y H, . Bivariate optimization for control design of interconnected uncertain nonlinear systems: A fuzzy set-theoretic approach. International Journal of Fuzzy Systems, 2018, 20(6): 1715–1729

[19]	Zhen S, Zhao H, Huang K, . A novel optimal robust control design of fuzzy mechanical systems. IEEE Transactions on Fuzzy Systems, 2015, 23(6): 2012–2023

[20]	Faber M, Johnston C, Schamhardt H C, . Three-dimensional kinematics of the equine spine during canter. Equine Veterinary Journal, 2001, 33(S33): 145–149

[21]	Smeathers J E. A mechanical analysis of the mammalian lumber spine. Dissertation for the Doctoral Degree. Reading: University of Reading, 1981

[22]	Grondin D E, Potvin J R. Effects of trunk muscle fatigue and load timing on spinal responses during sudden hand loading. Journal of Electromyography and Kinesiology, 2009, 19(4): e237–e245

[23]	Coros S, Karpathy A, Jones B, . Locomotion skills for simulated quadrupeds. ACM Transactions on Graphics, 2011, 30(4): 59

[24]	Zhu Y, Jin B, Li W, . Optimal design of a hexapod walking robot based on energy consumption and workspace. Transactions of the Canadian Society for Mechanical Engineering, 2014, 38(3): 305–317

[25]	Macpherson J M, Ye Y. The cat vertebral column: Stance configuration and range of motion. Experimental Brain Research, 1998, 119(3): 324–332

[26]	Faber M, Schamhardt H, Weeren R, . Basic three-dimensional kinematics of the vertebral column of horses walking on a treadmill. American Journal of Veterinary Research, 2000, 61(4): 399–406

[27]	Faber M, Johnston C, Schamhardt H C, . Basic three-dimensional kinematics of the vertebral column of horses trotting on a treadmill. American Journal of Veterinary Research, 2001, 62(5): 757–764

[28]	Zhu Y, Zhou S, Gao D, . Synchronization of non-linear oscillators for neurobiologically inspired control on a bionic parallel waist of legged robot. Frontiers in Neurorobotics, 2019, 13: 59

[29]	Zhu Y, Wu Y, Liu Q, . A backward control based on σ-Hopf oscillator with decoupled parameters for smooth locomotion of bio-inspired legged robot. Robotics and Autonomous Systems, 2018, 106: 165–178

[30]	Patricia W, Katherine K, Cornejo F. Primate Conservation Education. Hoboken: John Wiley & Sons, Inc., 2016, 1–11

[31]	Deban S M, Schilling N, Carrier D R. Activity of extrinsic limb muscles in dogs at walk, trot and gallop. Journal of Experimental Biology, 2012, 215(2): 287–300

[32]	Sabelhaus A P, Akella A K, Ahmad Z A, . Model-predictive control of a flexible spine robot. In: Proceedings of 2017 American Control Conference (ACC). Seattle: IEEE, 2017

[33]	Kawasaki R, Sato R, Kazama E, . Development of a flexible coupled spine mechanism for a small quadruped robot. In: Proceedings of 2016 IEEE International Conference on Robotics and Biomimetics (ROBIO). Qingdao: IEEE, 2016

[34]	Danner S M, Wilshin S D, Shevtsova N A, . Central control of interlimb coordination and speed dependent gait expression in quadrupeds. Journal of Physiology, 2016, 594(23): 6947–6967

[35]	Zhu Y G, Zhang L, Manoonpong P. Virtual motoneuron activation for goal-directed locomotion of a hexapod robot. In: Proceedings of 2020 5th International Conference on Advanced Robotics and Mechatronics (ICARM). Shenzhen: IEEE, 2020, 380–386

[36]	Zhu Y, Zhang L, Manoonpong P. Generic mechanism for waveform regulation and synchronization of oscillators: An application for robot behavior diversity generation. IEEE Transactions on Cybernetics, 2020 (in press)

[37]	Thor M, Manoonpong P. Error-based learning mechanism for fast online adaptation in robot motor control. IEEE Transactions on Neural Networks and Learning Systems, 2019, 31(6): 2042–2051

[38]	Ren G, Chen W, Dasgupta S, . Multiple chaotic central pattern generators with learning for legged locomotion and malfunction compensation. Information Sciences, 2015, 294: 666–682