K. Alipour, S.A.A. Moosavian, and Y. Bahramzadeh
[1] S.K. Saha & J. Angeles, Dynamics of nonholonomic mechanical systems using a natural orthogonal complement, ASME Journal of Applied Mechanics, 58, 1991, 238–244. [2] S.K. Saha & J. Angeles, Kinematics and dynamics of a three-wheeled 2-DOF AGV, Proc. IEEE Int. Conf. Robotics and Automation, Piscataway, USA, 1989, 1572–1577. [3] Z. Vafa & S. Dubowsky, On the dynamics of manipulators in space using the virtual manipulator approach, Proc. IEEE Int. Conf. Robotics and Automation, Raleigh, NC, 1987, 579–585. [4] E. Papadopoulos & S. Dubowsky, On the nature of control algorithms for free-floating space manipulators, IEEE Transactions on Robotics and Automation, 7 (6), 1991, 750–758. [5] S.A.A. Moosavian & E. Papadopoulos, On the kinematics of multiple manipulator space free-flyers, Journal of Robotic Systems, 15 (4), 1998, 207–216. [6] S.A.A. Moosavian & E. Papadopoulos, Explicit dynamics of space free-flyers with multiple manipulators via SPACEMAPL, Journal of Advanced Robotics, 18 (2), 2004, 223–244. [7] R. Rastegari & S.A.A. Moosavian, Multiple impedance control of nonholonomic wheeled mobile robotic systems performing object manipulation tasks, Journal of Engineering Faculty, Tehran University, 39 (1), 2005, 15–30 (written in Persian). [8] E. Papadopoulos & J. Poulakakis, Planning and model-based control for mobile manipulators, Proc. IEEE/RSJ Int. Conf. Intelligent Robots and Systems, Takamatsu, Japan, October 2000, 1810–1815. [9] S.A.A. Moosavian & M. Eslamy, Object manipulation by multiple arms of a wheeled mobile robotic system, Proc. IEEE Int. Conf. Robotics, Automation & Mechatronics, China, June 2008. [10] R.F. Abo-Shanab, N. Sepehri, & Q. Wu, On dynamic modelling of robot manipulators: The method of virtual links, Proc. ASME Design Engineering Technical Conf., Montreal, Canada, Paper #DETC’02/MECH-34225, 2002. [11] R.F. Abo-Shanab & N. Sepehri, On dynamic stability of manipulators mounted on mobile platforms, Robotica, 19, 2001, 439–449. [12] R.F. Abo-Shanab & N. Sepehri, Effect of base compliance on the dynamic stability of mobile manipulators, Robotica, 20, 2002, 607–613. [13] R.F. Abo-Shanab & N. Sepehri, Tip-over stability of manipulator-like mobile hydraulic, ASME Journal of Dynamic Systems, Measurement, and Control, 127, 2005, 295–301. [14] Q. Yu & I.-M. Chen, A general approach to the dynamics of nonholonomic mobile manipulator systems, ASME Journal of Dynamic Systems, Measurement, and Control, 124, 2002, 512–521. [15] H.G. Tanner, K.J. Kyriakopoulos, & N.J. Krikelis, Modelling of multiple mobile manipulators handling a common deformable object, Journal of Robotic Systems, 15 (11), 1998, 599–623. [16] A. Meghdari, M. Durali, & D. Naderi, Investigating dynamic interaction between the one D.O.F. manipulator and vehicle of a mobile manipulator, Journal of Intelligent and Robotic Systems, 28, 2000, 277–290. [17] V.A. Sujan & S. Dubowsky, An optimal information method for mobile manipulator dynamic parameter identification, IEEE/ASME Transactions on Mechatronics, 2 (2), 2003, 215–225. [18] M. Prado, A. Simon, A. Perez, & F. Ezquerro, Effects of ground terrain irregularities on wheeled mobile robot, Robotica, 21, 2003, 143–152. [19] J. Park, S.G. Roh, H. Kim, H.-G. Lee, & H. Choi, Design of multilayered suspension mechanism for differential type mobile robot, Proc. Int. Conf. Control, Automation and System (ICCAS), South Korea, October 2003. [20] M. Eghtesad & D.S. Necsulescu, Experimental study of the dynamic based feedback linearization of an autonomous wheeled ground vehicle, Journal of Robotics and Autonomous Systems, 47, 2004, 47–63. [21] S.A.A. Moosavian & K. Alipour, Moment-height tip-over measure for stability analysis of mobile robotic systems, Proc. IEEE/RSJ Int. Conf. Intelligent Robots and Systems, Beijing, China, October 2006, 5546–5551. [22] S.A.A. Moosavian & K. Alipour, On the dynamic tip-over stability of wheeled mobile manipulators, International Journal of Robotics and Automation, 22 (4), 2007, 322–328. [23] S.A.A. Moosavian & K. Alipour, Tip-over stability of suspended wheeled mobile robots, Proc. IEEE Int. Conf. Mechatronics and Automation, China, August 2007, 1356–1361. [24] Y. Nakamura, Advanced robotics: Redundancy and optimization (Reading, MA: Addison-Wesely Publishing Company, 1991). [25] R. Siegwart & I.R. Nourbakhsh, Introduction to autonomous mobile robots (New Delhi: Prentice-Hall of India, 2005). [26] Z. Shiller, Obstacle traversal for space exploration, Proc. IEEE Int. Conf. Robotics and Automation, San Francisco, USA, April 2000, 989–994. [27] V. Kumar, M. ˇZefran, & J. Ostrowski, Motion planning and control of robots, Handbook of Industrial Robotics (New York: John Wiley and Sons, 1997). [28] E. Papadopoulos, I. Papadimitriou, & I. Poulakakis, Polynomial-based obstacle avoidance techniques for nonholonomic mobile manipulator systems, Journal of Robotics and Autonomous Systems, 41 (4), 2005, 229–247.
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