References: [1] Sweet, L.M., Good, M.C. (1984). Redefinition of the Robot Motion Control Problem: Effects of Plant Dynamics, Drive System Constraints, and User Requirements, 23rd IEEE Conf. on Decision and Control, p 724-732, Las Vegas, Nev, USA. [2] Asada, H., Ma, Z. D., Tokumaru, H. (1990). Inverse Dynamics of Flexible Robot Arms. MODELING and Computation for Trajectory Control, Journal of Dynamic Systems, Measurement and Control, 112 (2) 177-185. [3] Chien, M. C., Huang, A. C. (2007). Adaptive Control for Flexible-Joint Electrically Driven Robot with Time-Varying Uncertain ties, IEEE Transactions on Industrial Electronics, 54 (2) 1032- 1038. [4] Lechevin, N., Sicard, P. (1997). Observer Design for Flexible Joint Manipulators with Parameter Uncertainties, IEEE International Conference on Robotics and Automation (ICRA’97), vol. 3, p. 2547-2552, Albuquerque, NM, USA, (April). [5] Tomei, P. (1990). An Observer for Flexible Joint Robots, IEEE Transactions on Automatic Control, 35 (6) 739-743. [6] Hassanzadeh, I., Kharrati, H., Bonab, J.-R. (2008). Model Following Adaptive Control for a Robot with Flexible Joints, IEEE Canadian Conference on Electrical and Computer Engineering (CCECE’08), p. 1467-1472, Niagara Falls, Canada, (May). [7] Ahmad, M.A. (2008). Vibration and Input Tracking Control of Flexible Manipulator Using LQR with Non-Collocated PID Controller, 2nd UKSIM European Symposium on Computer Modelling and Simulation, p. 40-45, (September). [8] Yim, W. (2001). Adaptive Control of a Flexible Joint Manipulator, IEEE International Conference on Robotics and Automation (ICRA’01), p. 3441-3446, (May). [9] Oh, J. H., Lee, J. S. (1997). Control of Flexible Joint Robot System by Backstepping Design Approach, IEEE International Conference on Robotics and Automation (ICRA’97), vol. 4, p. 3435-3440, (April). [10] Ghorbel, F., Hung, J. Y., Spong, M. W. (1989). Adaptive Control of Flexible-Joint Manipulators, IEEE Control Systems Magazine, 9 (7) 9-13. [11] Moberg, S., Hanssen, S. (2008). On Feedback Linearization for Robust Tracking Control of Flexible Joint Robots, 17th IFACWorld Congress Seoul, Korea, (July). [12] Lin, L.C., Yuan, K. (2007). Control of Flexible Joint Robots via External Linearization Approach, Journal of Robotic Systems, 7 (1) 1-22. [13] Spong, M. W., Khorasani, K., Kokotovic, P. V. (1987). An Integral Manifold Approach to the Feedback Control of Flexible Joint Robots, IEEE Journal of Robotics and Automation, 3 (4) 291-300. [14] Yeon, J. S., Park, J. H. (2008). Practical Robust Control for Flexible Joint Robot Manipulators, IEEE International Conference on Robotics and Automation (ICRA’08), p. 3377-3382, (May). [15] Mondal, S., Mahanta, C. (2014). Adaptive Second Order Terminal Sliding Mode Controller for Robotic Manipulators, Journal of the Franklin Institute, 351 (4) 2356-2377. [16] Khalil, APA H. K. (2002). NonLinear Systems, 3rd Edition (prentice Hall). [17] Spong, M. W., Vidyasagar, M. (2006). Robot Dynamics and Control, John Wiley & Sons, New York, NY, USA. [18] Belhaouane, Moez, M., Ghariani, Faiez., M. (2010). Improved Results on Robust Stability Analysis and Stabilization for a Class of Uncertain Nonlinear Systems, Mathematical Problems in Engineering, vol. 2010, Article ID 724563. [19] Laila, D. S. (2003). Design and Analysis of Nonlinear Sampled Data Control Systems, PhD Dissertation-Department of Electrical and Electronics Engineering, the University of Melbourne, (April). [20] Mumtaz, F. (2009). Sampled Data Control Based on Discrete Time equivalent Models, PhD Dissertation-Department of Electrical Engineering, NUST College of Electrical and Mechanical Engineering, Pakistan. |