TY - JOUR
T1 - On the Liapunov-Krasovskii methodology for the ISS of systems described by coupled delay differential and difference equations
AU - Pepe, P.
AU - Karafyllis, I.
AU - Jiang, Z. P.
N1 - Funding Information:
The work of P. Pepe has been supported by the Italian MIUR Project PRIN 2005, the work of Z.-P. Jiang has been supported in part by the US National Science Foundation under grants ECS-0093176, OISE-0408925 and DMS-0504462.
Funding Information:
Zhong-Ping Jiang received the B.Sc. degree in mathematics from the University of Wuhan, Wuhan, China, in 1988, the M.Sc. degree in statistics from the Université de Paris-sud, France, in 1989, and the Ph.D. degree in automatic control and mathematics from the École des Mines de Paris, France, in 1993. From 1993 to 1998, he held visiting researcher positions with various institutions including INRIA (Sophia-Antipolis), France, the Australian National University, the University of Sydney, and University of California. In January 1999, he joined the Polytechnic University at Brooklyn, New York, where he is currently a Professor. His main research interests include stability theory, the theory of robust and adaptive nonlinear control, and their applications to underactuated mechanical systems, congestion control, wireless networks, multi-agent systems and cognitive science. Dr. Jiang has served as a Subject Editor for the International Journal of Robust and Nonlinear Control, and as an Associate Editor for Systems & Control Letters, IEEE Transactions on Automatic Control and European Journal of Control. Dr. Jiang is a recipient of the prestigious Queen Elizabeth II Fellowship Award from the Australian Research Council, the CAREER Award from the US National Science Foundation, and the Young Investigator Award from the NSF of China. Dr. Jiang is a Fellow of the IEEE.
PY - 2008/9
Y1 - 2008/9
N2 - The input-to-state stability of time-invariant systems described by coupled differential and difference equations with multiple noncommensurate and distributed time delays is investigated in this paper. Such equations include neutral functional differential equations in Hale's form (which model, for instance, partial element equivalent circuits) and describe lossless propagation phenomena occurring in thermal, hydraulic and electrical engineering. A general methodology for systematically studying the input-to-state stability, by means of Liapunov-Krasovskii functionals, with respect to measurable and locally essentially bounded inputs, is provided. The technical problem concerning the absolute continuity of the functional evaluated at the solution has been studied and solved by introducing the hypothesis that the functional is locally Lipschitz. Computationally checkable LMI conditions are provided for the linear case. It is proved that a linear neutral system in Hale's form with stable difference operator is input-to-state stable if and only if the trivial solution in the unforced case is asymptotically stable. A nonlinear example taken from the literature, concerning an electrical device, is reported, showing the effectiveness of the proposed methodology.
AB - The input-to-state stability of time-invariant systems described by coupled differential and difference equations with multiple noncommensurate and distributed time delays is investigated in this paper. Such equations include neutral functional differential equations in Hale's form (which model, for instance, partial element equivalent circuits) and describe lossless propagation phenomena occurring in thermal, hydraulic and electrical engineering. A general methodology for systematically studying the input-to-state stability, by means of Liapunov-Krasovskii functionals, with respect to measurable and locally essentially bounded inputs, is provided. The technical problem concerning the absolute continuity of the functional evaluated at the solution has been studied and solved by introducing the hypothesis that the functional is locally Lipschitz. Computationally checkable LMI conditions are provided for the linear case. It is proved that a linear neutral system in Hale's form with stable difference operator is input-to-state stable if and only if the trivial solution in the unforced case is asymptotically stable. A nonlinear example taken from the literature, concerning an electrical device, is reported, showing the effectiveness of the proposed methodology.
KW - Continuous time difference equations
KW - Delay differential equations
KW - Input-to-state stability
KW - Liapunov-Krasovskii functional
KW - Neutral systems
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U2 - 10.1016/j.automatica.2008.01.010
DO - 10.1016/j.automatica.2008.01.010
M3 - Article
AN - SCOPUS:50049086623
SN - 0005-1098
VL - 44
SP - 2266
EP - 2273
JO - Automatica
JF - Automatica
IS - 9
ER -