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The geometrical quantity in damped wave equations on a square

Published online by Cambridge University Press:  11 October 2006

Pascal Hébrard
Affiliation:
Institut Élie Cartan, Université de Nancy 1, BP 239 54506 Vandœuvre-lès-Nancy Cedex, France; [email protected]; [email protected]
Emmanuel Humbert
Affiliation:
Institut Élie Cartan, Université de Nancy 1, BP 239 54506 Vandœuvre-lès-Nancy Cedex, France; [email protected]; [email protected]
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Abstract

The energy in a square membrane Ω subject to constant viscous dampingon a subset $\omega\subset \Omega$ decays exponentially in timeas soon as ωsatisfies a geometrical condition known as the “Bardos-Lebeau-Rauch” condition. The rate $\tau(\omega)$ of this decay satisfies $\tau(\omega)= 2 \min( -\mu(\omega),g(\omega))$ (see Lebeau [Math.Phys. Stud.19 (1996) 73–109]). Here $\mu(\omega)$ denotes the spectral abscissa of thedamped wave equation operator and  $g(\omega)$ is a number called the geometrical quantity of ω and defined as follows.A ray in Ω is the trajectory generated by thefree motion of a mass-point in Ω subject to elastic reflections on theboundary. These reflections obey the law of geometrical optics.The geometrical quantity $g(\omega)$ is then defined as the upper limit (large timeasymptotics) of the average trajectory length. We give here an algorithm to compute explicitly $g(\omega)$ when ωis a finite union of squares.

Type
Research Article
Copyright
© EDP Sciences, SMAI, 2006

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References

Asch, M. and Lebeau, G., The spectrum of the damped wave operator for a bounded domain in $\mathbb{R}^2$ . Experiment. Math. 12 (2003) 227241. CrossRef
Bardos, C., Lebeau, G. and Rauch, J., Sharp sufficient conditions for the observation, control and stabilization of waves from the boundary. SIAM J. Control Optim. 30 (1992) 10241065. CrossRef
Benaddi, A. and Rao, B., Energy decay rate of wave equations with infinite damping. J. Diff. Equ. 161 (2000) 337357. CrossRef
Carlos, C. and Cox, S., Achieving arbitrarily large decay in the damped wave equation. SIAM J. Control Optim. 39 (2001) 17481755.
A. Chambert-Loir, S. Fermigier and V. Maillot, Exercices de mathématiques pour l'agrégation. Analyse I. Masson (1995).
Cox, S. and Zuazua, E., The rate at which energy decays in a damping string. Comm. Partial Diff. Equ. 19 (1994) 213243. CrossRef
P. Hébrard, Étude de la géométrie optimale des zones de contrôle dans des problèmes de stabilisation. Ph.D. Thesis, University of Nancy 1 (2002).
Hébrard, P. and Henrot, A., Optimal shape and position of the actuators for the stabilization of a string. Syst. Control Lett. 48 (2003) 119209. CrossRef
G. Lebeau, Équation des ondes amorties, in Algebraic and Geometric Methods in Mathematical Physics. Kluwer Acad. Publ., Math. Phys. Stud. 19 (1996) 73–109.
Rauch, J. and Taylor, M., Decay of solutions to nondissipative hyperbolic systems on compact manifolds. Comm. Pure Appl. Math. 28 (1975) 501523. CrossRef
Sjostrand, J., Asymptotic distribution of eigenfrequencies for damped wave equations. Publ. Res. Inst. Sci. 36 (2000) 573611. CrossRef
S. Tabachnikov, Billiards mathématiques. SMF collection Panoramas et synthèses (1995).
Zuazua, E., Exponential decay for the semilinear wave equation with localized damping. Comm. Partial Equ. 15 (1990) 205235.