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2008 | OriginalPaper | Buchkapitel

29. Cooperative Manipulators

verfasst von : Fabrizio Caccavale, Prof, Masaru Uchiyama, Prof

Erschienen in: Springer Handbook of Robotics

Verlag: Springer Berlin Heidelberg

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Abstract

This chapter is devoted to cooperative manipulation of a common object by means of two or more robotic arms. The chapter opens with a historical overview of the research on cooperative manipulation, ranging from early 1970s to very recent years. Kinematics and dynamics of robotic arms cooperatively manipulating a tightly grasped rigid object are presented in depth. As for the kinematics and statics, the chosen approach is based on the so-called symmetric formulation; fundamentals of dynamics and reduced-order models for closed kinematic chains are discussed as well. A few special topics, such as the definition of geometrically meaningful cooperative task space variables, the problem of load distribution, and the definition of manipulability ellipsoids, are included to give the reader a complete picture of modeling and evaluation methodologies for cooperative manipulators. Then, the chapter presents the main strategies for controlling both the motion of the cooperative system and the interaction forces between the manipulators and the grasped object; in detail, fundamentals of hybrid force/position control, proportional–derivative (PD)-type force/position schemes, feedback linearization techniques, and impedance control approaches are given. In the last section further reading on advanced topics related to control of cooperative robots is suggested; in detail, advanced nonlinear control strategies are briefly discussed (i.e., intelligent control approaches, synchronization control, decentralized control); also, fundamental results on modeling and control of cooperative systems possessing some degree of flexibility are briefly outlined.

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Literatur
29.1.
S. Fujii, S. Kurono: Coordinated computer control of a pair of manipulators, Proc. 4th IFToMM World Congress (Newcastle upon Tyne 1975) pp. 411–417
29.2.
E. Nakano, S. Ozaki, T. Ishida, I. Kato: Cooperational control of the anthropomorphous manipulator ʼMELARMʼ, Proc. 4th Int. Symp. Ind. Robots (Tokyo 1974) pp. 251–260
29.3.
K. Takase, H. Inoue, K. Sato, S. Hagiwara: The design of an articulated manipulator with torque control ability, Proc. 4th Int. Symp. Ind. Robots (Tokyo 1974) pp. 261–270
29.4.
S. Kurono: Cooperative control of two artificial hands by a mini-computer, Prepr. 15th Joint Conf. on Automatic Control (1972) pp. 365–366, (in Japanese)
29.5.
A.J. Koivo, G.A. Bekey: Report of workshop on coordinated multiple robot manipulators: planning, control, and applications, IEEE J. Robot. Autom. 4(1), 91–93 (1988)
29.6.
P. Dauchez, R. Zapata: Co-ordinated control of two cooperative manipulators: the use of a kinematic model, Proc. 15th Int. Symp. Ind. Robots (Tokyo 1985) pp. 641–648
29.7.
N.H. McClamroch: Singular systems of differential equations as dynamic models for constrained robot systems, Proc. 1986 IEEE Int. Conf. on Robotics and Automation (San Francisco 1986) pp. 21–28
29.8.
T.J. Tarn, A.K. Bejczy, X. Yun: New nonlinear control algorithms for multiple robot arms, IEEE Trans. Aerosp. Electron. Syst. 24(5), 571–583 (1988)CrossRef
29.9.
S. Hayati: Hybrid position/force control of multi-arm cooperating robots, Proc. 1986 IEEE Int. Conf. on Robotics and Automation (San Francisco 1986) pp. 82–89
29.10.
M. Uchiyama, N. Iwasawa, K. Hakomori: Hybrid position/force control for coordination of a two-arm robot, Proc. 1987 IEEE Int. Conf. on Robotics and Automation (Raleigh 1987) pp. 1242–1247
29.11.
M. Uchiyama, P. Dauchez: A symmetric hybrid position/force control scheme for the coordination of two robots, Proc. 1988 IEEE Int. Conf. on Robotics and Automation (Philadelphia 1988) pp. 350–356
29.12.
M. Uchiyama, P. Dauchez: Symmetric kinematic formulation and non-master/slave coordinated control of two-arm robots, Adv. Robot. 7(4), 361–383 (1993)CrossRef
29.13.
I.D. Walker, R.A. Freeman, S.I. Marcus: Analysis of motion and internal force loading of objects grasped by multiple cooperating manipulators, Int. J. Robot. Res. 10(4), 396–409 (1991)CrossRef
29.14.
R.G. Bonitz, T.C. Hsia: Force decomposition in cooperating manipulators using the theory of metric spaces and generalized inverses, Proc. 1994 IEEE Int. Conf. on Robotics and Automation (San Diego 1994) pp. 1521–1527
29.15.
D. Williams, O. Khatib: The virtual linkage: a model for internal forces in multi-grasp manipulation, Proc. 1993 IEEE Int. Conf. on Robotics and Automation (Atlanta 1993) pp. 1025–1030
29.16.
K.S. Sang, R. Holmberg, O. Khatib: The augmented object model: cooperative manipulation and parallel mechanisms dynmaics, Proceedings of the 2000 IEEE International Conference on Robotics and Automation (San Francisco 1995) pp. 470–475
29.17.
J.T. Wen, K. Kreutz-Delgado: Motion and force control of multiple robotic manipulators, Automatica 28(4), 729–743 (1992)CrossRefMATHMathSciNet
29.18.
T. Yoshikawa, X.Z. Zheng: Coordinated dynamic hybrid position/force control for multiple robot manipulators handling one constrained object, Int. J. Robot. Res. 12, 219–230 (1993)CrossRef
29.19.
V. Perdereau, M. Drouin: Hybrid external control for two robot coordinated motion, Robotica 14, 141–153 (1996)CrossRef
29.20.
H. Bruhm, J. Deisenroth, P. Schadler: On the design and simulation-based validation of an active compliance law for multi-arm robots, Robot. Auton. Syst. 5, 307–321 (1989)CrossRef
29.21.
S.A. Schneider, R.H. Cannon Jr.: Object impedance control for cooperative manipulation: Theory and experimental results, IEEE Trans. Robot. Autom. 8, 383–394 (1992)CrossRef
29.22.
R.G. Bonitz, T.C. Hsia: Internal force-based impedance control for cooperating manipulators, IEEE Trans. Robot. Autom. 12, 78–89 (1996)CrossRef
29.23.
Y.-R. Hu, A.A. Goldenberg, C. Zhou: Motion and force control of coordinated robots during constrained motion tasks, Int. J. Robot. Res. 14, 351–365 (1995)CrossRef
29.24.
Y.-H. Liu, S. Arimoto: Decentralized adaptive and nonadaptive position/force controllers for redundant manipulators in cooperation, Int. J. Robot. Res. 17, 232–247 (1998)CrossRef
29.25.
P. Chiacchio, S. Chiaverini, B. Siciliano: Direct and inverse kinematics for coordinated motion tasks of a two-manipulator system, ASME J. Dyn. Syst. Meas. Contr. 118, 691–697 (1996)CrossRefMATH
29.26.
F. Caccavale, P. Chiacchio, S. Chiaverini: Task-Space regulation of cooperative manipulators, Automatica 36, 879–887 (2000)CrossRefMATHMathSciNet
29.27.
G.R. Luecke, K.W. Lai: A joint error-feedback approach to internal force regulation in cooperating manipulator systems, J. Robot. Syst. 14, 631–648 (1997)CrossRefMATH
29.28.
F. Caccavale, P. Chiacchio, S. Chiaverini: Stability analysis of a joint space control law for a two-manipulator system, IEEE Trans. Autom. Contr. 44, 85–88 (1999)CrossRefMATHMathSciNet
29.29.
P. Hsu: Coordinated control of multiple manipulator systems, IEEE Trans. Robot. Autom. 9, 400–410 (1993)CrossRef
29.30.
P. Chiacchio, S. Chiaverini, L. Sciavicco, B. Siciliano: Global task space manipulability ellipsoids for multiple arm systems, IEEE Trans. Robot. Autom. 7, 678–685 (1991)CrossRef
29.31.
S. Lee: Dual redundant arm configuration optimization with task-oriented dual arm manipulability, IEEE Trans. Robot. Autom. 5, 78–97 (1989)CrossRef
29.32.
T. Kokkinis, B. Paden: Kinetostatic performance limits of cooperating robot manipulators using force-velocity polytopes, Proc. of ASME Winter Annual Meeting–robotics Research (San Francisco 1989)
29.33.
P. Chiacchio, S. Chiaverini, L. Sciavicco, B. Siciliano: Task space dynamic analysis of multiarm system configurations, Int. J. Robot. Res. 10, 708–715 (1991)CrossRef
29.34.
D.E. Orin, S.Y. Oh: Control of force distribution in robotic mechanisms containing closed kinematic chains, Trans. ASME J. Dyn. Syst. Meas. Contr. 102, 134–141 (1981)CrossRef
29.35.
Y.F. Zheng, J.Y.S. Luh: Optimal load distribution for two industrial robots handling a single object, Proc. 1988 IEEE Int. Conf. on Robotics and Automation (Philadelphia 1988) pp. 344–349
29.36.
I.D. Walker, S.I. Marcus, R.A. Freeman: Distribution of dynamic loads for multiple cooperating robot manipulators, J. Robot. Syst. 6, 35–47 (1989)CrossRefMATH
29.37.
M. Uchiyama: A unified approach to load sharing, motion decomposing, and force sensing of dual arm robots, Robotics Research: 5th Int. Symp., ed. by H. Miura, S. Arimoto (MIT, 1990) pp. 225–232
29.38.
M.A. Unseren: A new technique for dynamic load distribution when two manipulators mutually lift a rigid object. Part 1: The proposed technique, Proc. First World Automation Congress (WAC ʼ94), Vol. 2 (Maui 1994) pp. 359–365
29.39.
M.A. Unseren: A new technique for dynamic load distribution when two manipulators mutually lift a rigid object. Part 2: Derivation of entire system model and control architecture, Proc. First World Automation Congress (WAC ʼ94), Vol. 2 (Maui 1994) pp. 367–372
29.40.
M. Uchiyama, T. Yamashita: Adaptive load sharing for hybrid controlled two cooperative manipulators, Proc. 1991 IEEE Int. Conf. on Robotics and Automation (Sacramento 1991) pp. 986–991
29.41.
M. Uchiyama, Y. Kanamori: Quadratic programming for dextrous dual-arm manipulation. In: Robotics, Mechatronics and Manufacturing Systems, Trans. IMACS/SICE Int. Symp. on Robotics, Mechatronics and Manufacturing Systems, Kobe, Japan, September 1992, ed. by T. Takamori, K. Tsuchiya (Elsevier, North-Holland 1993) pp. 367–372
29.42.
Y.F. Zheng, M.Z. Chen: Trajectory planning for two manipulators to deform flexible beams, Proc. 1993 IEEE Int. Conf. on Robotics and Automation (Atlanta 1993) pp. 1019–1024
29.43.
M.M. Svinin, M. Uchiyama: Coordinated dynamic control of a system of manipulators coupled via a flexible object, Prepr. 4th IFAC Symp. on Robot Control (Capri 1994) pp. 1005–1010
29.44.
T. Yukawa, M. Uchiyama, D.N. Nenchev, H. Inooka: Stability of control system in handling of a flexible object by rigid arm robots, Proc. 1996 IEEE Int. Conf. on Robotics and Automation (Minneapolis 1996) pp. 2332–2339
29.45.
M. Yamano, J.-S. Kim, A. Konno, M. Uchiyama: Cooperative control of a 3D dual-flexible-arm robot, J. Intell. Robot. Syst. 39, 1–15 (2004)CrossRef
29.46.
T. Miyabe, A. Konno, M. Uchiyama, M. Yamano: An approach toward an automated object retrieval operation with a two-arm flexible manipulator, Int. J. Robot. Res. 23, 275–291 (2004)CrossRef
29.47.
M. Uchiyama, A. Konno: Modeling, controllability and vibration suppression of 3D flexible robots. In: Robotics Research, The 7th Int. Symp, ed. by G. Giralt, G. Hirzinger (Springer, London 1996) pp. 90–99
29.48.
K. Munawar, M. Uchiyama: Slip compensated manipulation with cooperating multiple robots, 36th IEEE CDC (San Diego 1997)
29.49.
D. Sun, J.K. Mills: Adaptive synchronized control for coordination of multirobot assembly tasks, IEEE Trans. Robot. Autom. 18, 498–510 (2002)CrossRef
29.50.
A. Rodriguez-Angeles, H. Nijmeijer: Mutual synchronization of robots via estimated state feedback: a cooperative approach, IEEE Trans. Contr. Syst. Technol. 12, 542–554 (2004)CrossRef
29.51.
K.-Y. Lian, C.-S. Chiu, P. Liu: Semi-decentralized adaptive fuzzy control for cooperative multirobot systems with H-inf motion/internal force tracking performance, IEEE Trans. Syst. Man Cybern. – Part B: Cybernetics 32, 269–280 (2002)CrossRef
29.52.
W. Gueaieb, F. Karray, S. Al-Sharhan: A robust adaptive fuzzy position/force control scheme for cooperative manipulators, IEEE Trans. Contr. Syst. Technol. 11, 516–528 (2003)CrossRef
29.53.
J. Gudiño-Lau, M.A. Arteaga, L.A. Muñoz, V. Parra-Vega: On the control of cooperative robots without velocity measurements, IEEE Trans. Contr. Syst. Technol. 12, 600–608 (2004)CrossRef
29.54.
H. Inoue: Computer controlled bilateral manipulator, Bull. JSME 14(69), 199–207 (1971)
29.55.
M. Uchiyama, T. Kitano, Y. Tanno, K. Miyawaki: Cooperative multiple robots to be applied to industries, Proc. World Automation Congress (WAC ʼ96), Vol. 3 (Montpellier 1996) pp. 759–764
29.56.
B.M. Braun, G.P. Starr, J.E. Wood, R. Lumia: A framework for implementing cooperative motion on industrial controllers, IEEE Trans. Robot. Autom. 20, 583–589 (2004)CrossRef
29.57.
D. Sun, J.K. Mills: Manipulating rigid payloads with multiple robots using compliant grippers, IEEE/ASME Trans. Mechatron. 7, 23–34 (2002)CrossRef
29.58.
J.Y.S. Luh, Y.F. Zheng: Constrained relations between two coordinated industrial robots for motion control, Int. J. Robot. Res. 6, 60–70 (1987)CrossRef
29.59.
A.J. Koivo, M.A. Unseren: Reduced order model and decoupled control architecture for two manipulators holding a rigid object, ASME J. Dyn. Syst. Meas. Contr. 113, 646–654 (1991)CrossRefMATH
29.60.
M.A. Unseren: Rigid body dynamics and decoupled control architecture for two strongly interacting manipulators manipulators, Robotica 9, 421–430 (1991)CrossRef
29.61.
J. Duffy: The fallacy of modern hybrid control theory that is based on ``Orthogonal Complementsʼʼ of twist and wrench spaces, J. Robot. Syst. 7, 139–144 (1990)CrossRef
29.62.
K.L. Doty, C. Melchiorri, C. Bonivento: A theory of generalized inverses applied to robotics, Int. J. Robot. Res. 12, 1–19 (1993)CrossRef
29.63.
O. Khatib: Object manipulation in a multi-effector robot system,. In: Robotics Research, Vol. 4, ed. by R. Bolles, B. Roth (MIT Press, Cambridge 1988) pp. 137–144
29.64.
O. Khatib: Inertial properties in robotic manipulation: An object level framework, Int. J. Robot. Res. 13, 19–36 (1995)CrossRef
29.65.
F. Caccavale, L. Villani: Impedance control of cooperative manipulators, Mach. Intell. Robot. Contr. 2, 51–57 (2000)
Metadaten
Titel
Cooperative Manipulators
verfasst von
Fabrizio Caccavale, Prof
Masaru Uchiyama, Prof
Copyright-Jahr
2008
Buch
Springer Handbook of Robotics

Print ISBN: 978-3-540-23957-4

Electronic ISBN: 978-3-540-30301-5

Copyright-Jahr: 2008

DOI
https://doi.org/10.1007/978-3-540-30301-5_30

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