Dynamically Adapt to Uneven Terrain Walking Control for Humanoid Robot 被引量：3

Dynamically Adapt to Uneven Terrain Walking Control for Humanoid Robot

下载PDF

导出

摘要 Dynamically adapt to uneven ground locomotion is a crucial ability for humanoid robots utilized in human environments.However,because of the effect of current pattern generation method,adapting to unknown rough ground is limited.Moreover,to maintain large support region by four-point contact during the landing phase is usually a key problem.In order to solve these problems,a landing phase control and online pattern generation in three dimensional environments is proposed.On the basis of robot-environment non-planar interactive modes,a method of landing control based on optimal support region is put forward to realize stable four-point contact by flexible foot,and a controller is employed to adapt to the changes of ground without using prior knowledge.Furthermore,an adaptable foothold planning is put forward to the online pattern generation considering walking speed,uneven terrain,and the effect of lateral movement to the locomotion stability.Finally,the effectiveness of landing control and online pattern generation is demonstrated by dynamic simulations and real robot walking experiments on outdoor uneven ground.The results indicate that the robot kept its balance even though the ground is unknown and irregular.The proposed methods lay a foundation for studies of humanoid robots performing tasks in complex environments. Dynamically adapt to uneven ground locomotion is a crucial ability for humanoid robots utilized in human environments.However,because of the effect of current pattern generation method,adapting to unknown rough ground is limited.Moreover,to maintain large support region by four-point contact during the landing phase is usually a key problem.In order to solve these problems,a landing phase control and online pattern generation in three dimensional environments is proposed.On the basis of robot-environment non-planar interactive modes,a method of landing control based on optimal support region is put forward to realize stable four-point contact by flexible foot,and a controller is employed to adapt to the changes of ground without using prior knowledge.Furthermore,an adaptable foothold planning is put forward to the online pattern generation considering walking speed,uneven terrain,and the effect of lateral movement to the locomotion stability.Finally,the effectiveness of landing control and online pattern generation is demonstrated by dynamic simulations and real robot walking experiments on outdoor uneven ground.The results indicate that the robot kept its balance even though the ground is unknown and irregular.The proposed methods lay a foundation for studies of humanoid robots performing tasks in complex environments.

作者 WEI Hui SHUAI Mei WANG Zhongyu

机构地区 School of Instrumentation Science and Opto-electronics Engineering School of Automation Science and Electrical Engineering

出处《Chinese Journal of Mechanical Engineering》 SCIE EI CAS CSCD 2012年第2期214-222,共9页 中国机械工程学报（英文版）

基金 supported by National Natural Science Foundation of China (Grant No. 50775008) the PhD Programs Foundation of Ministry of Education of China (Grant No. 200800061019) Hubei provincial Digital Manufacturing Key Laboratory Foundation of China (Grant No.SZ0602)

关键词 humanoid robots landing control online gait generation uneven terrain humanoid robots landing control online gait generation uneven terrain

分类号 TP242 [自动化与计算机技术—检测技术与自动化装置] TU623.5 [建筑科学—建筑技术科学]

引文网络
相关文献

参考文献1

1王剑,秦海力,绳涛,马宏绪.仿人机器人的不平整地面落脚控制方法[J].机器人,2010,32(2):210-218. 被引量：9

二级参考文献17

1Hirose M, Haikawa Y, Takenaka T, et al Development of humanoid robot ASIMO[C]//IEEE/RSJ International Conference on Intelligent Robots and Systems. Piscataway, N J, USA: IEEE, 2001: 1321-1326.
2Tanie K. Humanoid robot and its application possibility[C]// IEEE Conference on Multisensor Fusion and Integration for Intelligent Systems. Piscataway, NJ, USA: IEEE, 2003: 213-218.
3Inoue H, Tachi S. Overview of humanoid robotics project of METI[C]//Intemational Symposium on Robotics. 2001: 1478- 1482.
4Swinson M L, Bruemmer D J. Expanding frontiers of humanoid robotics[J]. 1EEE Intelligent Systems and Their Applications, 2000, 15(4): 12-16.
5Hashimoto K, Sugahara Y, Sunazuka H, et al. Biped landing pattern modification method with nonlinear compliance control[C]//IEEE International Conference on Robotics and Automation. Piscataway, NJ, USA: IEEE, 2006: 1213-1218.
6Kang T K, Song H, Kim D, et al. Environment recognition system for biped walking robot using vision based sensor fusion[M]//Lecture Notes in Computer Science, vol.4570. Berlin, Germany: Springer-Verlag, 2007: 405-414.
7Kagami S, Nishiwaki K, Kuffner J, et al. Online 3D vision, motion planning and biped locomotion control coupling system of humanoid robot: H7[C]//IEEE/RSJ International Conference on Intelligent Robots and Systems. Piscataway, NJ, USA: IEEE, 2002: 2557-2562.
8Chew C, Pratt J, Pratt G. Blind walking of planar bipedal robot on sloped terrain[C]//lEEE International Conference on Robotics and Automation. Piscataway, NJ, USA: IEEE, 1999: 122-127.
9Morisawa M, Tsuji T, Nishioka Y, et al. Contact motion in unknown environment[C]//IEEE International Conference on Robotics and Automation. Piscataway, NJ, USA: IEEE, 2003: 992-996.
10Wang J, Sheng T, Ma H X, et al. Design and dynamic walking control of humanoid robot Blackmann[C]//6th World Congress on Intelligent Control and Automation. Piscataway, NJ, USA: IEEE, 2006: 8848-8852.

共引文献8

1付根平,杨宜民,李静.仿人机器人的步行控制方法综述及展望[J].机床与液压,2011,39(23):154-159. 被引量：7
2李鹏,顾宏斌,吴东苏,刘晖.头盔伺服系统的主动柔顺控制[J].航空学报,2012,33(5):928-939. 被引量：3
3梅红,李云霞,李文阁.一种具有爬坡越障能力的移动机器人[J].机床与液压,2013,41(22):14-16. 被引量：5
4王坤,刘荣海,杨迎春,郑欣,李亚宁,万书亭.四轮机器人整体结构建模分析[J].云南电力技术,2017,45(1):50-55. 被引量：1
5张永清,王岩.基于武术擂台赛仿人机器人的开发研究[J].河北建筑工程学院学报,2017,35(1):110-112.
6张永清,马立勇,郭成帅,李博宇.武术擂台赛仿人机器人自身稳定性的研究与实现[J].河北建筑工程学院学报,2018,36(3):78-81.
7张永进,谢慧松,李庆庆,余张国.基于虚拟黏弹性肌肉模型的仿人机器人不平整地面稳定行走[J].机器人,2019,41(3):289-297. 被引量：1
8刘俊,阮小栋,杨鹏亮,吴迪,郑敏毅.变胞机器人重构及转向时足着地柔顺性控制[J].中国机械工程,2022,33(24):2917-2926. 被引量：2

同被引文献20

1CHENG Gang GE Shi-rong WANG Yong.Error Analysis of Three Degree-of-Freedom Changeable Parallel Measuring Mechanism[J].Journal of China University of Mining and Technology,2007,17(1):101-104. 被引量：7
2QI Ming,QIE Yanhui.FORWARD KINEMATICS ANALYSIS FOR A NOVEL 5-DOF PARALLEL MECHANISM USING TETRAHEDRON CONFIGURATIONS[J].Chinese Journal of Mechanical Engineering,2007,20(6):1-4. 被引量：3
3GUI AN Q, GONZALEZ A F, MARKUS N. Constrainteffects for a reactor pressure vessel subjected topressurized thermal shockfJ]. Procedia MaterialsScience, 2014, 3(1): 1687-1693.
4ILYA B, FLORIN C. Contributions to thermal constraintsmanagement in radial active distribution systems[J].Electric Power Systems Research, 2014,111(11):169-176.
5KLOCKEF, LUNGD, PULS H. FEM-modelling of thethermal workpiece deformation in dry tuming[J].Procedia CIRP, 2013, 8(12): 240-245.
6KAMRANA, MANOUCHEHRS, MEHDI A. Transientthermal stresses in functionally graded thick truncatedcones by graded finite element method[J]. InternationalJournal of Pressure Vessels and Piping,2014, 119(1):52-61.
7LUO Zai, JIANG Wensong, GUO Bin, et al. Analysis ofseparation test for automatic brake adjuster based onlinear radon transformation[J]. Mechanical Systems andSignal Processing, 2014, 50(1): 526-534.
8BI Fengrong, SHAO Kang, LIU Changwen, et al.Analysis of thermoelasto hydrodynamic performance ofjournal misaligned engine main bearings卩].ChineseJournal of Mechanical Engineering, 2015,28(3): 511-520.
9JEON J, MULIANA A, SAPONARAVL. Thermal stressand deformation analyses in fiber reinforced polymercomposites undergoing heat conduction and mechanicalloading[J]. Composite Structures, 2014,5(11): 31-44.
10WANG Z, GAO S,QIN P. Detection of grossmeasurement errors using the grey system method[J]. TheInternational Journal of Advanced ManufacturingTechnology, 2002, 19(11): 801-804.

引证文献3

1Wei-Guo Wu,Wen-Qian Du.Research of 6-DOF Serial-Parallel Mechanism Platform for Stability Training of Legged-Walking Robot[J].Journal of Harbin Institute of Technology(New Series),2014,21(2):75-82. 被引量：1
2江文松,罗哉,胡晓峰,郭斌,王学影,王中宇.汽车制动自调臂的缺口盘热变形研究[J].机械工程学报,2015,51(22):82-87.
3杜国锋,邵士博,李尚霖,林诚然,曹政才.融合视觉语言模型与近端策略优化算法的人形机器人步态切换方法[J].机械工程学报,2025,61(21):204-212.

二级引证文献1

1吴伟国.面向作业与人工智能的仿人机器人研究进展[J].哈尔滨工业大学学报,2015,47(7):1-19. 被引量：37

1曲成义.物联网的发展态势和前景[J].信息化建设,2009(11):16-18. 被引量：16
2威尔.奈特.灵巧型机器人[J].科技创业,2014(5):28-31.
3易小刚.PLC在全液压推土机控制系统中的应用[J].制造业自动化,2003,25(8):65-68. 被引量：5
4李婷.化学建材开创绿色建筑的新时代[J].环球聚氨酯,2014,0(2):68-73.
5杨静,蒋国梁.浅谈混凝土新材料的开发与人居环境的改善[J].混凝土,1999(4):10-13. 被引量：9
6李红艳.加拿大城市空间的可持续发展实践及对我国的启示[J].建筑与文化,2016(9):56-60. 被引量：1
7冯艺全.开发“绿色建材”保护人类环境[J].广东建材,2004,27(11):58-60.
8MAN Cui-hua,FAN Xun,LI Cheng-rong,ZHAO Zhong-hui.Kinematics Analysis Based on Screw Theory of a Humanoid Robot[J].Journal of China University of Mining and Technology,2007,17(1):49-52. 被引量：2
9张彤,肖南峰.Plane extraction for navigation of humanoid robot[J].Journal of Central South University,2011,18(3):627-632.
10“全国非线性动力学、非线性振动和运动稳定性学术会议”在南京召开[J].振动与冲击,2004,23(4):118-118.

Chinese Journal of Mechanical Engineering

2012年第2期

浏览历史

内容加载中请稍等...