A bionic cerebellar motion control model and its application in arm control_Journal of Biomedical Engineering

Authors：

ZHANG Qi ,  LIU Rong , LI Yaozhu , LIANG Yabin , LIN Xiangqian

Liaoning Key Lab of Integrated Circuit and Biomedical Electronic System, School of Biomedical Engineering, Dalian University of Technology, Dalian, Liaoning 116024, P.R. China;

Corresponding author：

LIU Rong, Email: rliu@dlut.edu.cn

Keywords：

bionic; cerebellar model; neuron; motion control

DOI：

10.7507/1001-5515.201910052

Video：

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How to realize the control of limb movement and apply it to intelligent robot systems at the level of cerebellar cortical neurons is a hot topic in the fields of artificial intelligence and rehabilitation medicine. At present, the cerebellar model usually used is only for the purpose of controlling the effect, borrowing from the functional mode of the cerebellum, but it ignores the structural characteristics of the cerebellum. In fact, in addition to being used for controlling purposes, the cerebellar model should also have the interpretability of the control process and be able to analyze the consequences of cerebellar lesions. Therefore, it is necessary to establish a bionic cerebellar model which could better express the characteristics of the cerebellum. In this paper, the process that the cerebellum processes external input information and then generates control instructions at the neuron level was explored. By functionally segmenting the cerebellum into homogeneous structures, a novel bionic cerebellar motion control model incorporating all major cell types and connections was established. Simulation experiments and force feedback device control experiments show that the bionic cerebellar motion control model can achieve better control effect than the currently widely used cerebellar model articulation controller, which verifies the effectiveness of the bionic cerebellar motion control model. It has laid the foundation for real brain-like artificial intelligence control.

Citation： ZHANG Qi, LIU Rong, LI Yaozhu, LIANG Yabin, LIN Xiangqian. A bionic cerebellar motion control model and its application in arm control. Journal of Biomedical Engineering, 2020, 37(6): 1065-1072, 1079. doi: 10.7507/1001-5515.201910052 Copy

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1. Raymond J L, Medina J F. Computational principles of supervised learning in the cerebellum. Annu Rev Neurosci, 2018, 41(1): 233-253.
2. Cerri G, Esposti R, Locatelli M, et al. Coupling of hand and foot voluntary oscillations in patients suffering cerebellar ataxia: different effect of lateral or medial lesions on coordination. Prog Brain Res, 2005, 148: 227-241.
3. 朱波, 褚亚奇. 假肢中的感知及其反馈技术研究进展. 生物医学工程学杂志, 2019, 36(6): 1048-1054.
4. Albus J S. A new approach to manipulator control cerebellar model articulation control (CMAC). Transactions of the Same Journal of Dynamic Systems, 1975, 97(3): 220-227.
5. Chao Fei, Zhou Dajun, Lin C M, et al. Type-2 fuzzy hybrid controller network for robotic systems. IEEE Trans Cybern, 2020, 50(8): 3778-3792.
6. Lin C M, Huynh T T, Le T L. Adaptive TOPSIS fuzzy CMAC back-stepping control system design for nonlinear systems. Soft comput, 2019, 23(16): 6947-6966.
7. Huynh T T, Lin C M, Le T L, et al. A new self-organizing fuzzy cerebellar model articulation controller for uncertain nonlinear systems using overlapped gaussian membership functions. IEEE Transactions on Industrial Electronics, 2019, 67(11): 9671-9682. DOI: 10.1109/TIE.2019.2952790.
8. Solouki S, Pooyan M. Arrangement and applying of movement patterns in the cerebellum based on semi-supervised learning. Cerebellum, 2016, 15(3): 299-305.
9. Antonietti A, Martina D, Casellato C, et al. Control of a humanoid NAO robot by an adaptive bioinspired cerebellar module in 3D motion tasks. Comput Intell Neurosci, 2019, 2019: 4862157.
10. Sokolov A A, Miall R C, Ivry R B. The cerebellum: adaptive prediction for movement and cognition. Trends Cogn Sci, 2017, 21(5): 313-332.
11. Aisa B, Mingus B, O'reilly R. The emergent neural modeling system. Neural Netw, 2008, 21(8): 1146-1152.
12. 陈卫东, 陈攀攀, 朱奇光. 基于改进弹簧-质点模型的形变建模及力反馈算法研究. 生物医学工程学杂志, 2015, 32(5): 989-996.
13. Liu Xia, Jiang Wei, Dong Xiucheng. Nonlinear adaptive control for dynamic and dead-zone uncertainties in robotic systems. Int J Control Autom Syst, 2017, 15(2): 875-882.
14. Lin Xiangqian, Rong Liu. A distributed cerebellar-inspired learning model for robotic arm control. Annu Int Conf IEEE Eng Med Biol Soc, 2017: 929-932.

Journal of Biomedical Engineering

A bionic cerebellar motion control model and its application in arm control

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