收稿日期: 2023-01-10
网络出版日期: 2023-06-21
基金资助
国家自然科学基金面上项目(62073092);陕西省重点研发计划项目(2021ZDLGY09-02)
Learning and Generalization of Dual-Robot Cooperative Handling Trajectory Based on Dynamic Movement Primitives
Received date: 2023-01-10
Online published: 2023-06-21
Supported by
the General Program of National Natural Science Foundation of China(62073092);the Key R&D Plan Projects in Shaanxi Province(2021ZDLGY09-02)
针对双机器人协作系统执行具有强协调约束关系的仿人任务时,存在轨迹学习复杂、协调约束分析欠缺的问题,提出了基于动态运动基元(DMPs)的双机器人协同搬运轨迹学习及泛化方法。首先,从双机器人协同搬运任务出发,分析了双机器人协调约束关系,建立了双机器人运动约束模型。然后,将机器人运动轨迹解耦为位置轨迹和姿态轨迹,采用四元数实现姿态轨迹的无奇异描述,分别建立位置轨迹和姿态轨迹的动态运动基元模型,结合双机器人运动约束模型与动态运动基元模型,兼顾各自的任务要求和相对位姿约束,进而获得双机器人的运动轨迹。接着,开展了双机器人协同搬运轨迹的仿真与实验,结果表明:采用双机器人协同搬运轨迹的学习与泛化方法,当改变起、终点状态时,双机器人定姿态协同搬运的起、终点位置误差分别为0.029 2 mm和0.112 7 mm,变姿态协同搬运的起、终点位置误差分别为0.032 3 mm和0.113 1 mm,终点的四元数姿态偏差为0.001 4、0.002 7、0.001 8、0.003 0,表明该协同搬运轨迹的学习与泛化方法具有较高的运动控制精度,即使起、终点任务参数改变,泛化轨迹仍可保证目标的可达性,验证了提出的双机器人协调运动轨迹控制方法的合理性和有效性。该方法可学习人体搬运过程并能够准确泛化出新的运动轨迹,实现了双机器人的协调运动,具有重要的工程应用价值。
曹学鹏, 王德硕, 冯艳丽, 等 . 基于DMPs的双机器人协同搬运轨迹的学习与泛化[J]. 华南理工大学学报(自然科学版), 2023 , 51(12) : 9 -20 . DOI: 10.12141/j.issn.1000-565X.230013
Aiming at the problems of complex trajectory learning and lack of coordination constraint analysis when a dual-robot collaborative system performs humanoid tasks with strong coordination constraints, this paper proposed a dual-robot cooperative handling trajectory learning and generalization method based on dynamic movement primitives (DMPs). Firstly, starting from the dual-robot cooperative handling task, the coordination constraints of the dual-robot were analyzed, and the motion constraint model of the dual-robot was established. Then, the robot motion trajectory was decoupled into position trajectory and orientation trajectory, and the quaternion was used to realize the non-singular description of the orientation trajectory. And the dynamic movement primitives model of position trajectory and orientation trajectory were established respectively. They were combined with the dual robot motion constraint model and DMPs model, and the dual-robot movement trajectory was obtained, taking into account their respective task requirements and relative pose constraints. Finally, the simulation and experiments of the cooperative handling trajectory of the two robots were carried out. The results show that: using the learning and generalization method of the dual-robot cooperative handling trajectory, when the starting and ending states are changed, the position errors of start point and end point of the dual-robot cooperative handling with the fixed orientation are 0.029 2 mm and 0.112 7 mm respectively; the position errors of start point and end point of variable orientation coordinated handling are 0.032 3 mm and 0.113 1 mm respectively; and the quaternion orientation errors of the end point are 0.001 4, 0.002 7, 0.001 8, 0.003 0, indicating that the cooperative handling trajectory learning and generalization method has high motion control accuracy; even if the task parameters of the starting and ending are changed, the generalized trajectory can still ensure the accessibility of the target, which verified the scientificity and effectiveness of the proposed dual-robot coordination motion trajectory control strategy. The method proposed in this paper can effectively learn the human handling process and can accurately generalize new motion trajectories. It realizes the dual-robot coordinated motion and has important engineering application value.
| 1 | JI W, WANG L .Industrial robotic machining:a review[J].The International Journal of Advanced Manufacturing Technology,2019,103(1):1239-1255. |
| 2 | BIEN Z, LEE J .A minimum-time trajectory planning method for two robots[J].IEEE Transactions on Robotics and Automation,1992,8(3):414-418. |
| 3 | PETAR C, BOJAN J .Dual-arm robot motion planning based on cooperative coevolution[J].Emerging Trends in Technological Innovation,2010,314(6):169-178. |
| 4 | SMITH C, KARAYIANNIDIS Y, NALPANTIDIS L,et al .Dual arm manipulation-a survey[J].Robotics and Autonomous Systems,2012,60(10):1340-1353. |
| 5 | GAN Y H, DAI X .Kinematic cooperation analysis and trajectory teaching in multiple robots system for welding[C]∥Proceedings of ETFA 2011.Toulouse:IEEE,2011:1-8. |
| 6 | LI J, LIU Y, ZANG X .Constraints analysis and motion planning for coordinated manipulation of a dual-arm robot[C]∥Proceedings of 2018 IEEE International Conference on Information and Automation (ICIA).Wuyi Mountain:IEEE,2018:1422-1426. |
| 7 | GULLETTA G, ERLHAGEN W, BICHO E .Human-like arm motion generation:a review[J].Robotics,2020,9(4):102-149. |
| 8 | SCHAAL S .Is imitation learning the route to humanoid robots?[J].Trends in Cognitive Sciences,1999,3(6):233-242. |
| 9 | KOENIG N, MATARIC M .Robot life-long task learning from human demonstrations:a Bayesian approach[J],Autonomous Robots,2017,41(5):1173-1188. |
| 10 | PIGNAT E, CALINON S .Learning adaptive dressing assistance from human demonstration[J].Robotics and Autonomous Systems,2017,93:61-75. |
| 11 | SHIN S Y, KIM C H .Human-like motion generation and control for humanoid’s dual arm object manipulation[J].IEEE Transactions on Industrial Electronics,2014,62(4):2265-2276. |
| 12 | QU J, ZHANG F, WANG Y,et al .Human-like coordination motion learning for a redundant dual-arm robot[J].Robotics and Computer-Integrated Manufacturing,2019,57:379-390. |
| 13 | IJSPEERT A J, NAKANISHI J, HOFFMANN H,et al .Dynamical movement primitives:learning attractor models for motor behaviors[J].Neural Computation,2013,25(2):328-373. |
| 14 | COHEN Y, BARSHIR O, BERMAN S .Motion adaptation based on learning the manifold of task and dynamic movement primitive parameters[J].Robotica,2021,39(7):1299-1315. |
| 15 | KULVICIUS T, BIEHL M, AEIN M J,et al .Interaction learning for dynamic movement primitives used in cooperative robotic tasks[J].Robotics and Autonomous Systems,2013,61(12):1450-1459. |
| 16 | UMLAUFT J, SIEBER D, HIRCHE S .Dynamic movement primitives for cooperative manipulation and synchronized motions[C]∥Proceedings of 2014 IEEE International Conference on Robotics and Automation (ICRA).Hong Kong:IEEE,2014:766-771. |
| 17 | ZHAO T, DENG M, LI Z,et al .Cooperative manipulation for a mobile dual-arm robot using sequences of dynamic movement primitives[J].IEEE Transactions on Cognitive and Developmental Systems,2018,12(1):18-29. |
| 18 | 孟石,戴先中,甘亚辉 .多机器人协作系统轨迹约束关系分析及示教方法[J].机器人,2012,34(5):546-552,565. |
| MENG Shi, DAI Xian-zhong, GAN Ya-hui .Path constraint relation and trajectory teaching method for multi-robot cooperation System[J].Robot,2012,34(5):546-552,565. | |
| 19 | 张磊,王威 .双机器人协同搬运运动学分析及路径规划[J].机械工程与自动化,2020(2):89-91,94. |
| ZHANG Lei, WANG Wei .Kinematics analysis and path planning of dual-robot collaborative handling [J].Mechanical Engineering and Automation,2020(2):89-91,94. | |
| 20 | IJSPEERT A J, NAKANISHI J, SCHAAL S .Movement imitation with nonlinear dynamical systems in humanoid robots[C]∥Proceedings of 2002 IEEE International Conference on Robotics and Automation.Washington,DC:IEEE,2002:1398-1403. |
| 21 | HOFFMANN H, PASTOR P, PARK D H,et al .Biologically-inspired dynamical systems for movement generation:automatic real-time goal adaptation and obstacle avoidance[C]∥Proceedings of 2009 IEEE International Conference on Robotics and Automation.Kobe:IEEE,2009:2587-2592. |
| 22 | UDE A, NEMEC B, PETRIC T,et al .Orientation in cartesian space dynamic movement primitives[C]∥Proceedings of 2014 IEEE International Conference on Robotics and Automation (ICRA).Hong Kong:IEEE,2014:2997-3004. |
| 23 | 张磊,方灶军,王聚幸,等 .基于任务参数加权的动态运动基元泛化方法[J].中国机械工程,2022,33(10):1226-1233,1243. |
| ZHANG Lei, FANG Zao-jun, WANG Ju-xing,et al .Generalization method of dynamic movement primitives based on the weighting of task parameters[J].China Mechanical Engineering,2022,33(10):1226-1233,1243. | |
| 24 | SOLA J .Quaternion kinematics for the error-state Kalman filter[J].arXiv preprint arXiv:,2017. |
| 25 | 王健发,王耀南,陈文锐,等 .基于改进动态运动基元的6D轨迹规划[J].控制理论与应用,2022,39(5):809-818. |
| WANG Jian-fa, WANG Yao-nan, CHEN Wen-rui,et al .6D trajectory planning based on improved dynamic motion primitives[J].Control Theory and Applications,2022,39(5):809-818. | |
| 26 | 工业机器人性能规范及其试验方法: [S]. |
/
| 〈 |
|
〉 |
地址:广州 五山 华南理工大学17号楼 邮政编码:510640
电话: 020-87111794 邮箱:journal@scut.edu.cn
