An Approach for Adaptive Limbless Locomotion Using a CPG-Based Reflex Mechanism 被引量：2

An Approach for Adaptive Limbless Locomotion Using a CPG-Based Reflex Mechanism

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摘要 Animals＇ free movement in natural environments has attracted many researchers to explore control methods for bio-inspired robots. This paper presents a novel reflex mechanism based on a Central Pattern Generator （CPG） for adaptive locomotion of limbless robots. First, inspired by the concept of reflex arc, the reflex mechanism is designed on a connectionist CPG model. Since the CPG model inspired by the spinal cord of lampreys is developed at the neuron level, it provides a possible natural solution for sensory reflex integration. Therefore, sensory neurons that bridge the external stimuli and the CPG model, together with the concept of reflex arc, are utilized for designing the sensory reflex mechanism. Then, a border reflex and a body reflex are further developed and applied on the ends and the middle part of a limbless robot, respectively. Finally, a ball hitting scenario and a corridor passing scenario are designed to verify the proposed method. Results of simulations and on-site experiments show the feasibility and effectiveness of the reflex mechanism in realizing fast response and adaptive limbless locomotion. Animals＇ free movement in natural environments has attracted many researchers to explore control methods for bio-inspired robots. This paper presents a novel reflex mechanism based on a Central Pattern Generator （CPG） for adaptive locomotion of limbless robots. First, inspired by the concept of reflex arc, the reflex mechanism is designed on a connectionist CPG model. Since the CPG model inspired by the spinal cord of lampreys is developed at the neuron level, it provides a possible natural solution for sensory reflex integration. Therefore, sensory neurons that bridge the external stimuli and the CPG model, together with the concept of reflex arc, are utilized for designing the sensory reflex mechanism. Then, a border reflex and a body reflex are further developed and applied on the ends and the middle part of a limbless robot, respectively. Finally, a ball hitting scenario and a corridor passing scenario are designed to verify the proposed method. Results of simulations and on-site experiments show the feasibility and effectiveness of the reflex mechanism in realizing fast response and adaptive limbless locomotion.

作者 Guoyuan Li Houxiang Zhang Jianwei Zhang Hans Petter Hildre

机构地区 Faculty of Maritime Technology and Operations Department of Computer Science

出处《Journal of Bionic Engineering》 SCIE EI CSCD 2014年第3期389-399,共11页 仿生工程学报（英文版）

关键词 sensory reflex mechanism reflex arc central pattern generator limbless locomotion sensory reflex mechanism, reflex arc, central pattern generator, limbless locomotion

分类号 TP393.07 [自动化与计算机技术—计算机应用技术] TP18 [自动化与计算机技术—控制理论与控制工程]

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参考文献3

1Chengju LIU,Qijun CHEN,Guoxing WANG.Adaptive walking control of quadruped robots based on central pattern generator (CPG) and reflex[J].控制理论与应用（英文版）,2013,11(3):386-392. 被引量：5
2Yueri Cai,Shusheng Bi,Licheng Zheng Robotics Institute,Beihang University,Beijing 100191,P.R.China.Design and Experiments of a Robotic Fish Imitating Cow-Nosed Ray[J].Journal of Bionic Engineering,2010,7(2):120-126. 被引量：22
3Thanhtam Ho,Sunghac Choi,Sangyoon Lee.Development of a Biomimetic Quadruped Robot[J].Journal of Bionic Engineering,2007,4(4):193-199. 被引量：8

二级参考文献25

1Shao-bo Yang,Jing Qiu,Xiao-yun HanInstitute of Mechatronical Engineering and Automatization,National University of Defense Technology,Changsha 410073,P.R.China.Kinematics Modeling and Experiments of Pectoral Oscillation Propulsion Robotic Fish[J].Journal of Bionic Engineering,2009,6(2):174-179. 被引量：25
2A. J. Ijspeert. Central pattern generators for locomotion control in animals and robots: a review. Neural Networks, 200S, 21 (4): 642 - 653.
3Q. Wu, C. Liu. Q. Chen, er al. Survey of locomotion control of legged robots inspired by biological concept. Science in China - Series F: information Sciences. 2009. 52( 10): 2235 - 2240.
4G. Brown. On the nature of the fundamental activity of the nervous centres; together with an analysis of the conditioning of rhythmic activity in progression, and a theory of the evolution of function in the nervous system. Journal of Physiology, 1914, 48(1): 18 - 46.
5N. Krouchev, J. F. Kalaska, T. Drew. Sequential activation of muscle synergies during locomotion in the intact cat as revealed by cluster analysis and direct decomposition. Journal of Neurophysiology, 2006, 96(4): 1991 -2010.
6I. A. Rybak, N. A. Shevtsova, M. Lafreniere-Roula, et al. Modelling spinal circuity involved in locomotor pattern generation: insights from deletions during ficitive locomotion . Journal of Physiology, 2006, 577(2): 617 - 639.
7K. Seo, S. J. Chung, J. J. E. Slotine. CPG-based control of a turtle-like underwater vehicle. Autonomous Robots, 2010. 2S(3): 247 - 269.
8K. Seo, S. J. Chung, J. J. E. Slotine. Adaptive creeping locomotion of a CPG-controlled snake-like robot to environment change. Autonomous Robots, 2010, 2S(3): 283 - 294.
9J. K. Ryu, N. Y. Chong, B. J You. Locomotion of snake-like robots using adaptive neural oscillators. Intelligent Service Robotics, 2010, 3(1): 1-10.
10A. J. ljspeert, A. Crespi, D. Ryczko, et al. From swimming to walking with a salamander robot driven by a spinal cord model. Science, 2007, 315(5817): 1416-1420.

共引文献32

1Thanhtam Ho,Sangyoon Lee.Piezoelectrically Actuated Biomimetic Self-Contained Quadruped Bounding Robot[J].Journal of Bionic Engineering,2009,6(1):29-36.
2张颖,朱兴龙.仿生爬行机器人研究中的关键技术[J].徐州工程学院学报（自然科学版）,2009,24(3):50-55. 被引量：1
3蔡月日,毕树生.胸鳍摆动推进模式仿生鱼研究进展[J].机械工程学报,2011,47(19):30-37. 被引量：14
4魏清平,王硕,谭民,王宇.仿生机器鱼研究的进展与分析[J].系统科学与数学,2012,32(10):1274-1286. 被引量：31
5张锦荣,李锋,张建华.采用虚拟样机技术的四足机器人仿真研究[J].现代制造工程,2013(4):26-29. 被引量：2
6王田苗,杨兴帮,梁建宏.中央鳍/对鳍推进模式的仿生自主水下机器人发展现状综述[J].机器人,2013,35(3):352-362. 被引量：32
7Fei Gao Zhenlong Wang Yukui Wang Yangwei Wang Jian Li.A Prototype of a Biomimetic Mantle Jet Propeller Inspired by Cuttlefish Actuated by SMA Wires and a Theoretical Model for Its Jet Thrust[J].Journal of Bionic Engineering,2014,11(3):412-422. 被引量：4
8牛传猛,毕树生,蔡月日,张利格,马宏伟.胸鳍摆动推进仿生鱼的设计及水动力实验[J].机器人,2014,36(5):535-543. 被引量：7
9陈伟海,刘涛,王建华,任冠佼,吴星明.仿生六足机器人传感信息处理及全方向运动控制[J].浙江大学学报（工学版）,2015,49(3):430-438. 被引量：6
10Guoyuan Li,Wei Li,Jianwei Zhang,Houxiang Zhang.Analysis and Design of Asymmetric Oscillation for Caterpillar-Like Locomotion[J].Journal of Bionic Engineering,2015,12(2):190-203. 被引量：4

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2Kyung-min Lee,Youngshik Kim,Jamie K. Paik,Buhyun Shin.Clawed Miniature Inchworm Robot Driven by Electromagnetic Oscillatory Actuator[J].Journal of Bionic Engineering,2015,12(4):519-526. 被引量：7

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1Jizhuang Fan,Yu Zhang,Hongzhe Jin,Xiaolu Wang,Dongyang Bie,Jie Zhao,Yanhe Zhu.Chaotic CPG Based Locomotion Control for Modular Self-reconfigurable Robot[J].Journal of Bionic Engineering,2016,13(1):30-38.
2Chang-Woo Song,Dong-Jun Lee,Seung-Yop Lee.Bioinspired Segment Robot with Earthworm-like Plane Locomotion[J].Journal of Bionic Engineering,2016,13(2):292-302. 被引量：5

二级引证文献5

1Buhyun Shin,Youngshik Kim,Jamie Paik,Kyung-min Lee.Miniaturized Twin-legged Robot with an Electromagnetic Oscillatory Actuator[J].Journal of Bionic Engineering,2018,15(1):106-113. 被引量：2
2张东光,左国标,佟金,张智泓.蚯蚓仿生注液沃土装置设计与试验[J].农业工程学报,2019,35(19):29-36. 被引量：3
3何子瀚,方虹斌,徐鉴.仿蚯蚓移动机器人离散步态控制与相位差控制特性比较[J].机器人,2020,42(6):697-708. 被引量：5
4Bingzhu Wang,Xiangrui Ye.Finite Element Simulation Analysis of a Novel 3D-FRSPA for Crawling Locomotion[J].Computer Modeling in Engineering & Sciences,2024,139(5):1401-1425.
5Yu Liu,Qingbiao Shi,Zhen Chen.Design and Gait Planning of a Worm-inspired Metameric Robot for Pipe Crawling[J].Journal of Bionic Engineering,2024,21(3):1265-1277.

1成新.穿上机器人瘫痪能走路[J].科海故事博览,2011(23):60-60.
2王煜全.网络如何智能化[J].互联网周刊,2009(13):81-81.
3谁说手机一定要是直的？[J].传奇天下（职教新航线）,2016(3):6-6.
4新西兰：截肢男子成为首位机械手指佩戴者[J].中国残疾人,2016,0(8):23-23.
5Pamda 朱若涵(译).重置按钮[J].英语广场,2014,0(9):69-71.
6刘劲松.安装假肢的误区[J].中国残疾人,2008(2):63-63.
7韩欣欣.单反数码相机的优缺点[J].家电科技（制冷空调．维修）,2005(10).
8姚丁杨.当互联网遇到神经学[J].百科知识,2016,0(7):24-26.
9委内瑞拉男子截肢三个月后自制高效仿生手臂[J].创新时代,2013(8):15-15.
10康普340米多模光缆实现100G GE[J].微电脑世界,2011(4):102-102.

Journal of Bionic Engineering

2014年第3期

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