Stability Analysis of Fractional Order Systems with Time Delay
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Stability Analysis of Fractional Order Systems with Time Delay

Authors: Hong Li, Shou-Ming Zhong, Hou-Biao Li

Abstract:

In this paper, we mainly study the stability of linear and interval linear fractional systems with time delay. By applying the characteristic equations, a necessary and sufficient stability condition is obtained firstly, and then some sufficient conditions are deserved. In addition, according to the equivalent relationship of fractional order systems with order 0 < α ≤ 1 and with order 1 ≤ β < 2, one may get more relevant theorems. Finally, two examples are provided to demonstrate the effectiveness of our results.

Keywords: Fractional order systems, Time delay, Characteristic equation.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1092146

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References:


[1] I. Podlubuy, Fractional differential equations. New York: Academic Press, 1999.
[2] B. O’Neill, R. Jeanloz, Geophys. Res. Lett. 17 (1990) 1477.
[3] J.J. Ita, L. Stixrude, J. Geophys. Res. 97 (1992) 6849.
[4] A. Oustaloup, X. Morean, M. Nouiuant, The CRONE suspension. Control Eng. Pract. 4(8)(1996) 1101-1108.
[5] B.J. Lurie, Tunable TID controller. US Patent 5, 371, 630, December 6, 1944.
[6] I. Podlubuy, Fractional-order systems and PIλDu-controllers, IEEE Trans. Automat. Control, 44(1)(1999) 208-214.
[7] D. Matignon, Stability results on fractional differential equations to control processing, in: peocessings of Computational Engineering in Syatems and Application Multiconference, vol.2, IMACS, IEEE-SMC, 1996, 963-968.
[8] Y.X. Sheng, J.G. Lu, Robust stability and stabilization of fractional-order linear systems with nonlinear ncertain parameters: An LMI approach, Chaos, Solitons and Fractals, 42(2009) 1163-1169.
[9] J. Sabatier, M. Moze, C. Farges, LMI stability conditions for fractional order systems. Computers and Mathematics with Applications, 59(2010) 1594-1609.
[10] J.G. Lu, Y.Q. Chen, Robust stability and stabilization of fractional-order interval systems with the Fractional Order α: The 0 < α < 1 Case, IEEE Transactions on Automatic Control, 55(1) 2010, 152-158.
[11] H.S. Ahn, Y.Q. Chen, I.Podlubny, Robust stability test of a class of linear time-invariant interval fractional-order system using Lypunov inequality. Applied Mathematics and Computation, 187(1) 2007, 27-34.
[12] J.C. Trigeassou, N. Maamri, J. Sabatier, A. Oustaloup, A Lyapunov approach to the stability of fractional differential equations. Signal Processing, 91(2011) 437-44.
[13] M.P. Lazarevi´c, Finite time stability analysis of fractional control of robotic time-delay systems: Gronwall’s approach, Mathematical and Computer Modelling, 49(2009) 475-481.
[14] M.P. Lazarevi´c,A.M. Spasi´c, Finite-time stability analysis of fractional order time-delay systems, San Diego, 1999.
[15] Z. Liao, C. Peng, W. Li, Y. Wang, Robust Stability Analysis for a class of Fractional order Systems with Uncertain Parameters, Journal of the Franklin Institute, 348(2011) 1101-1113.
[16] Tingzhu Huang, Shouming Zhong and Zhengliang Li, Matrix Theory. Beijing, Higher Education Press, 2003.
[17] Weihua Deng, Changpin Li, Jinhu L¨u, Stability analysis of linear fractional differential system with multiple time delays, Nonlinear Dyn., 48(2007) 409-416.
[18] Hong Li, Shou-ming Zhong and Hou-biao Li. Stability of Interval Fractional-order systems with order 0 < α < 1. International Journal of Computational and Mathematical Sciences, 6 (2012): 89-93.