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Stabilization method for the Saint-Venant equations by boundary control

Hassen Arfaoui

2020Transactions of the Institute of Measurement and Control16 citationsDOI

Abstract

In this paper, we are interested in the stabilization of the flow modeled by the Saint-Venant equations. We have solved two problems in this study. The first, we have proved that the operator associated to the Saint-Venant system has a finite number of unstable eigenvalues. Consequently, the system is not exponentially stable on the space [Formula: see text], but is exponentially stable on a subspace of the space [Formula: see text], ([Formula: see text] is a given domain). The second problem, if the advection is dominant, the natural stabilization is very slow. To solve these problems, we have used an extension method due to Russel (1974) and Fursikov (2002). Thanks to this method, we have determined a boundary Dirichlet control able to accelerate the stabilization of the flow. Also, the boundary Dirichlet control is able to kill all the unstable eigenvalues to get an exponentially stable solution on the space [Formula: see text]. Then, we extend this method to the finite difference equations analog of the continuous Saint-Venant equations. Also, in this case, we obtained similar results of stabilization. A finite difference scheme is used to compute the control and several numerical experiments are performed to illustrate the efficiency of the control.

Topics & Concepts

MathematicsBoundary (topology)Dirichlet boundary conditionEigenvalues and eigenvectorsMathematical analysisFinite differenceVon Neumann stability analysisBoundary value problemFlow (mathematics)Applied mathematicsNeumann boundary conditionGeometryPhysicsQuantum mechanicsStability and Controllability of Differential EquationsAdvanced Mathematical Modeling in EngineeringAdvanced Mathematical Physics Problems