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Expansion of source equation of elastic line

Published online by Cambridge University Press:  01 November 2008

Mirjana Filipovic  and
Miomir Vukobratovic
Mirjana Filipovic*
Affiliation:
Mihajlo Pupin Institute, Volgina 15, 11000 Belgrade, Serbia. E-mail: vuk@robot.imp.bg.ac.yu
Miomir Vukobratovic
Affiliation:
Mihajlo Pupin Institute, Volgina 15, 11000 Belgrade, Serbia. E-mail: vuk@robot.imp.bg.ac.yu
*
*Corresponding author. E-mail: mira@robot.imp.bg.ac.yu
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Summary

The paper is concerned with the relationship between the equation of elastic line motion, the “Euler-Bernoulli approach” (EBA), and equation of motion at the point of elastic line tip, the “Lumped-mass approach” (LMA). The Euler–Bernoulli equations (which have for a long time been used in the literature) should be expanded according to the requirements of the motion complexity of elastic robotic systems. The Euler–Bernoulli equation (based on the known laws of dynamics) should be supplemented with all the forces that are participating in the formation of the bending moment of the considered mode. This yields the difference in the structure of Euler–Bernoulli equations for each mode. The stiffness matrix is a full matrix. Mathematical model of the actuators also comprises coupling between elasticity forces. Particular integral of Daniel Bernoulli should be supplemented with the stationary character of elastic deformation of any point of the considered mode, caused by the present forces. General form of the elastic line is a direct outcome of the system motion dynamics, and can not be described by one scalar equation but by three equations for position and three equations for orientation of every point on that elastic line. Simulation results are shown for a selected robotic example involving the simultaneous presence of elasticity of the joint and of the link (two modes), as well the environment force dynamics.

Keywords

RobotModelingElastic deformationGearLinkCouplingDynamicsKinematicsTrajectory planning
Type
Article
Information
Robotica , Volume 26 , Issue 6 , November 2008 , pp. 739 - 751
Copyright
Copyright © Cambridge University Press 2008

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References

1.Vukobratovic, M., Potkonjak, V. and Matijević, V., “Control of robots with elastic joints interacting with dynamic environment,” J. Intel. Robot Syst. 23, 87100 (1998).CrossRefGoogle Scholar
2.Book Maizza-Neto and Whitney, “Feedback control of two beam, two joint systems with distributed flexibility,” Trans ASME J. Dyn. Syst. Meas. Control 97G(4), 424431 (1975).CrossRefGoogle Scholar
3.Hughes, P. C., “Dynamic of a Flexible Manipulator Arm for the Space Shuttle,” AIAA Astrodynamics Conference, Grand Teton National Park, Wyoming, USA (1977).Google Scholar
4.Moallem, M., Khorasani, K. and Patel, V. R., “Tip Position Tracking of Flexible Multi-Link Manipulators: An Integral Manifold Approach,” IEEE International Conference on Robotics and Automation, Minneapolis, Minnesota (Apr. 1996) pp. 24322436.Google Scholar
5.Matsuno, F., Wakashiro, K. and Ikeda, M., “Force Control of a Flexible Arm,” International Conference on Robotics and Automation, San Diego, CA, USA (May 1994) pp. 21072112.Google Scholar
6.Matsuno, F. and Kanzawa, T., “Robust Control of Coupled Bending and Torsional Vibrations and Contact Force of a Constrained Flexible Arm,” International Conference on Robotics and Automation, Minneapolis, Minnesota (1996) pp. 24442449.CrossRefGoogle Scholar
7.Yim, W., “Modified Nonlinear Predictive Control of Elastic Manipulators,” International Conference on Robotics and Automation, Minneapolis, Minnesota (Apr. 1996) pp. 20972102.CrossRefGoogle Scholar
8.Surdilovic, D. and Vukobratovic, M., “One method for efficient dynamic modeling of flexible manipulators,” Mech. Mach. Theory. 31 (3), 297315 (1996).CrossRefGoogle Scholar
9.Surdilovic, D. and Vukobratovic, M., “Deflection compensation for large flexible manipulators,” Mech. Mach. Theory 31 (3), 317329 (1996).CrossRefGoogle Scholar
10.Spong, M. W., “On the force control problem for flexible joint manipulators,” IEEE Trans. on Autom. Control 34 (1) (Jan. 1989) pp. 107111.CrossRefGoogle Scholar
11.Ghorbel, F. and Spong, M. W., “Adaptive Integral Manifold Control of Flexible Joint Robot Manipulators,” IEEE International Conference on Robotics and Automation, Nice, France (May 1992) pp. 707714.Google Scholar
12.Krishnan, H., “An Approach to Regulation of Contact Force and Position in Flexible-Link Constrained Robots,” IEEE, Vancouver (1995) pp. 20872092.Google Scholar
13.Cheong, J., Chung, W. and Youm, Y., “Bandwidth Modulation of Rigid Subsystem for the Class of Flexible Robots,” Proceedings Conference on Robotics and Automation, San Francisco, USA (Apr. 2000) pp. 14781483.Google Scholar
14.Low, H. K., “A systematic formulation of dynamic equations for robot manipulators with elastic links,” J Robot. Syst. 4 (3), 435456 (Jun 1987).Google Scholar
15.Low, H. K. and Vidyasagar, M., “A Lagrangian formulation of the dynamic model for flexible manipulator systems,” ASME J Dyn. Syst., Meas.t Control 110 (2), 175181(Jun 1988).CrossRefGoogle Scholar
16.Low, H. K., “Solution schemes for the system equations of flexible robots,” J. Robot. Syst. 6 (4), 383405 (Aug. 1989).CrossRefGoogle Scholar
17.Bayo, E., “A finite-element approach to control the end-point motion of a single-link flexible robot,” J. Robot. Syst. 4 (1), 6375 (1987).CrossRefGoogle Scholar
18.De Luca, A., “Feedforward/Feedback Laws for the Control of Flexible Robots,” IEEE Intern Conf. on Robotics and Automation, San Francisco, CA (Apr. 2000) pp. 233240.Google Scholar
19.Spong, M. W., “Modeling and control of elastic joint robots,” ASME J. Dyn. Syst Meas. Control 109, 310319 (1987).CrossRefGoogle Scholar
20.Filipović, M. and Vukobratović, M., “Modeling of Flexible Robotic Systems,” Computer as a Tool, EUROCON 2005, The International Conference, Belgrade, Serbia and Montenegro, (Nov. 21–24, 2005) Vol. 2, pp. 11961199.CrossRefGoogle Scholar
21.Filipović, M. and Vukobratović, M., “Contribution to modeling of elastic robotic systems,” Eng. Autom. Probl Int. J. 5 (1), 2235 (Sep. 23, 2006).Google Scholar
22.Filipović, M., Potkonjak, V. and Vukobratović, M.: “Humanoid robotic system with and without elasticity elements walking on an immobile/mobile platform,” J. Intel. Robot. Syst. Int. J. 48, 157186 (2007).CrossRefGoogle Scholar
23.Meirovitch, L., Analytical Methods in Vibrations (Macmillan: New York, 1967).Google Scholar
24.Matsuno, F. and Sakawa, Y.: “Modeling and quasi-static hybrid position/force control of constrained planar two-link flexible manipulators,” IEEE Trans. Robot. Autom. 10 (3) (Jun 1994).CrossRefGoogle Scholar
25.Kim, J. S., Siuzuki K, K.. and Konno, A., “Force Control of Constrained Flexible Manipulators,” International Conference on Robotics and Automation, Minneapolis, Minnesota (Apr. 1996) pp. 635640.Google Scholar
26.De Luka, A. and Siciliano, B., “Closed-form dynamic model of planar multilink lightweight robots,” IEEE Trans. Syst., Man Cybern. 21, 826839 (Jul./Aug. 1991).CrossRefGoogle Scholar
27.Jang, H., Krishnan, H. and Ang, M. H. Jr., “A Simple Rest-to-Rest Control Command for a Flexible Link Robot,” IEEE International Conference on Robotics and Automation (1997) pp. 3312–3317.Google Scholar
28.Cheong, J., Chung, W. K. and Youm, Y., “PID Composite Controller and Its Tuning for Flexible Link Robots,” Proceedings of the 2002 IEEE/RSJ, International Conference on Intelligent Robots and Systems EPFL, Lausanne, Switzerland (Oct. 2002) pp. 21222128.Google Scholar
29.Khadem, S. E. and Pirmohammadi, A. A., “Analytical development of dynamic equations of motion for a three-dimensional flexible link manipulator with revolute and prismatic joints,” IEEE Trans. Syst. Man Cybern., part B: Cybernetics 33 (2) (Apr. 2003).CrossRefGoogle ScholarPubMed
30.Book, W. J. and Majette, M., “Controller design for flexible, distributed parameter mechanical arms via combined state space and frequency domain techniques,” Trans ASME J. Dyn. Syst. Meas. Control 105, 245254 (1983).CrossRefGoogle Scholar
31.Book, W. J., “Recursive Lagrangian dynamics of flexible manipulator arms,” Int. J. Robot. Res. 3 (3) (1984).CrossRefGoogle Scholar
32.Book, W. J., “Analysis of massless elastic chains with servo controlled joints,” Trans. ASME J. Dyn. Syst. Meas. And Control 101, 187192 (1979).CrossRefGoogle Scholar
33.Strutt, J. W. and Rayligh, Lord, “Theory of Sound,” second publish, Mc. Millan & Co., London and New York (1894–1896) paragraph 186.Google Scholar
34.Timoshenko, S. and Young, D. H., Vibration Problems in Engineering (D. Van Nostrand Company: New York, 1955).Google Scholar
35.Potkonjak, V. and Vukobratovic, M., “Dynamics in contact tasks in robotics, Part I: General model of robot interacting with dynamic environment,” Mech. Mach. Theory 33 (1999).Google Scholar