Control Algorithm of Successive Iteration of Vector Field for Physical Human-Robot Interaction

China Mechanical Engineering ›› 2014, Vol. 25 ›› Issue (17): 2337-2343.

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Control Algorithm of Successive Iteration of Vector Field for Physical Human-Robot Interaction

Xie Guanghui1,2;Yang Zhiping2;Wang Guangjian1

1.State Key Laboratory of Mechanical Transmission,Chongqing University,Chongqing,400044
2.Chongqing College of Electronic Engineering,Chongqing,401331

Online:2014-09-10 Published:2014-09-22
Supported by:
Natural Science Foundation of Chongqing（No. cstc2012jjA40028）

矢量场逐次迭代的人-机身体交流控制

谢光辉1,2;杨治平2;王光建1

1.重庆大学机械传动国家重点实验室，重庆，400044
2.重庆电子工程职业学院，重庆，401331

基金资助:
国家留学基金委资助项目(2007102654);重庆市自然科学基金资助项目(cstc2012jjA40028);重庆市教委科学技术研究项目(KJ112203)

Abstract

Abstract:

In order to synchronize motions between robot and human, a control method for physical human-robot interaction was proposed by using successive iteration of vector field. The attractor corresponding with target trace of robot was introduced in 3 dimensional space. The vector field system with any target trajectory was designed by successive iteration for the 3D space, so that it could realize the synchronization between joint torque information as an input signal and desired trajectory of each robot joint as an output signal, and the strength of the synchronization could be varied by adjusting some internal parameters value in the vector field system. It was analyzed that the mutual interactions for two dynamics had different vector fields. Finally, the presented dynamics was applied to the control simulation of lower limb power-assisted robot, and it was analyzed that the joint torque components influenced synchronous movement. Simulation results prove the validity of the proposed control method.

Key words: physical human-robot interaction, successive iteration design, vector field, threshold value

摘要：

为使人和机器人在身体交流中保持运动协调同步，提出了基于矢量场逐次迭代的人-机身体交流智能控制方法。对智能控制方法中具有任意目标轨迹的三维空间矢量场逐次迭代系统进行算法设计，使其输出的关节期望位移信号能与输入的扭矩信号保持同步，且同步强度要达到能实现参数可调的目的;分析了具备不同矢量场的两个逐次迭代系统的相互作用情况;以人和机器人身体交流的典型例子——下肢外骨骼助力机器人为对象，对该智能控制方法进行了应用仿真,并分析了关节扭矩成分对同步运动的影响。仿真结果表明该控制方法有效。

关键词: 人和机器人身体交流, 逐次迭代设计, 矢量场, 阈值

CLC Number:

TP24

Xie Guanghui, Yang Zhiping, Wang Guangjian. Control Algorithm of Successive Iteration of Vector Field for Physical Human-Robot Interaction[J]. China Mechanical Engineering, 2014, 25(17): 2337-2343.

谢光辉, 杨治平, 王光建 . 矢量场逐次迭代的人-机身体交流控制[J]. 中国机械工程, 2014, 25(17): 2337-2343.

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Control Algorithm of Successive Iteration of Vector Field for Physical Human-Robot Interaction

矢量场逐次迭代的人-机身体交流控制

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