T. Renugadevi scite author profile

This paper focuses on the stabilization problem for the linear parabolic system using the backstepping method. The exponentially stability results for considered parabolic system are derived in two cases with Dirichlet and Neumann local terms. Also, the boundary conditions for the problem is assumed to be mixed or Robin-type boundary conditions. The main aim is to achieve the stability of the considered system using the backstepping method with help of Volterra integral transformation. The explicit solutions of kernel functions in integral transformation is obtained by using Laplace transform and designed a boundary control law to the closed-loop system. Finally, the effectiveness and applicability of the derived results are validated through a single-species pattern generation model.

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T. Renugadevi

Boundary stabilization and state estimation of ODE-transport PDE with in-domain coupling

Observer and boundary output feedback control for coupled ODE-transport PDE

Boundary state feedback control for semilinear fractional-order reaction diffusion systems

Results on Boundary Control for Parabolic Systems Using Backstepping Method

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