Title :
Absolute stability of a heterogeneous semilinear dissipative parabolic PDE
Author_Institution :
United Technol. Res. Center, East Hartford, CT, USA
Abstract :
We analyze absolute stability of the equilibrium solution of a semilinear dissipative parabolic PDE with a spatially varying nonlinearity that satisfies a given sector condition. Stability is shown based on Lyapunov analysis of the infinite-dimensional dynamics. The pertinent linear operators are expressed in terms of their infinite-dimensional matrix representations, some of which have a Toeplitz structure due to the spatial heterogeneity of the nonlinearity. The time derivative of the Lyapunov function is expressed as a sum of finite-dimensional expressions. The analysis is described in terms of finite-dimensional linear matrix inequalities (LMI). Sufficient conditions, in terms of a finite set of finite-dimensional LMI, are given to establish absolute stability. Numerical simulations are presented for a system with Dirichlet boundary conditions with spatially varying saturation nonlinearities.
Keywords :
Lyapunov methods; absolute stability; control nonlinearities; linear matrix inequalities; multidimensional systems; parabolic equations; partial differential equations; Dirichlet boundary conditions; Lyapunov analysis; Toeplitz structure; absolute stability; equilibrium solution; finite dimensional expressions; finite-dimensional linear matrix inequalities; heterogeneous semilinear dissipative parabolic PDE; infinite-dimensional dynamics; infinite-dimensional matrix representations; linear operators; spatially varying saturation nonlinearities; Boundary conditions; Feedback loop; Linear matrix inequalities; Linear systems; Lyapunov method; Nonlinear dynamical systems; Nonlinear equations; Numerical simulation; Stability analysis; Sufficient conditions;
Conference_Titel :
Decision and Control, 2004. CDC. 43rd IEEE Conference on
Print_ISBN :
0-7803-8682-5
DOI :
10.1109/CDC.2004.1428771
