Asymptotic Analysis - Volume 22, issue 3-4

Authors: Perelman, Galina

Article Type: Research Article

Abstract: We describe the long time behavior of the resonant states for a class of Hamiltonians adiabatically depending on time in the case where the lifetime of the resonance is comparable with the adiabatic scale.

Citation: Asymptotic Analysis, vol. 22, no. 3-4, pp. 177-203, 2000

Authors: Kateb, Djalil | Seghier, Abdellatif

Article Type: Research Article

Abstract: Let \tilde\varLambda be a polytope in \mathbb{R}^d , \varLambda =\tilde\varLambda \cap\mathbb{Z}^{d} be its trace on the group \mathbb{Z}^{d} and let T_{\varLambda }(f) be a Toeplitz operator, with a positive symbol f\in L^{\infty}(\mathbb{T}^{d}) , defined on the Hardy space H^2(\varLambda ) . With some additional assumptions on f , a purely algebraic inverse formula of T_{\varLambda }(f) is given. The geometric properties of the operators are highlighted when \varLambda is inflated to get \varLambda _\lambda =\lambda \varLambda with \lambda=2^{m} …chosen sufficiently large. A localization result for the inverse operator is obtained. When we are sufficiently close to a (d-k) ‐dimensional face of the inflated polytope, the localized inversion formula is reduced to those operators reflecting this proximity. Subsequently an analogue of the strong Szegő limit theorem is stated; a d+1 order asymptotics formula of the trace of the inverse is given that connects each operator of the sum with some geometric measures of our polytope (volume, area,\,\ldots ). Furthermore, the results of Thorsen and Doktorski are retrieved with the help of the Ehrart lattice enumerator formula. Show more

Citation: Asymptotic Analysis, vol. 22, no. 3-4, pp. 205-234, 2000

Authors: Miranville, Alain

Article Type: Research Article

Abstract: Our aim in this article is to discuss some questions related to the existence and uniqueness of solutions and on the existence of finite dimensional attractors for Cahn–Hilliard type equations. Compared to the classical Cahn–Hilliard equation, these models take into account the anisotropy of the material, the work of internal microforces and the deformations of the material.

Keywords: Cahn–Hilliard equation, internal microforces, elastic material, deformations, global attractor

Citation: Asymptotic Analysis, vol. 22, no. 3-4, pp. 235-259, 2000

Authors: Gustafsson, Björn | Heron, Bernard | Mossino, Jacqueline

Article Type: Research Article

Abstract: We consider energy functionals, or Dirichlet forms, J_\varOmega^\varepsilon(u)= \int_\varOmega (A^\varepsilon \nabla u, \nabla u) \,\mathrm{d}x= \sum^N_{i,j=1} \, \int_\varOmega a^\varepsilon_{ij} \, \frac{\curpartial u}{\curpartial x_i} \, \frac{\curpartial u}{\curpartial x_j} \,\mathrm{d}x, for a class \mathcal{G} of bounded domains \varOmega\subset\mathbb{R}^N , with \varepsilon >0 a fine structure parameter and with symmetric conductivity matrices A^\varepsilon=(a^\varepsilon_{ij})\in L_\mathrm{loc}^\infty(\mathbb{R})^{N\times N} which are functions only of the first coordinate x_1 and which are locally uniformly elliptic for each fixed \varepsilon>0 . We show that if the functions (of x_1 ) b^\varepsilon_{11}={1}/{a^\varepsilon_{11}} …, b^\varepsilon_{1j}={a^\varepsilon_{1j}}/{a^\varepsilon_{11}}\ (j\geq 2) , b^\varepsilon_{ij}= a^\varepsilon_{ij} - {a^\varepsilon_{i1}a^\varepsilon_{1j}}/{a^\varepsilon_{11}} \ (i, j\geq 2) converge weakly* as measures towards corresponding limit measures b_{ij} as \varepsilon\to 0 , if the (1,1) ‐coefficient m_{11}^\varepsilon of (A^\varepsilon)^{-1} is bounded in L_\mathrm{loc}^1(\mathbb{R}) and if none of its weak* cluster measures has atoms in common with b_{ii} , i\geq 2 , then the family J^\varepsilon=\{J_\varOmega^\varepsilon \}_{\varOmega\in \mathcal{G}} \varGamma ‐converges in a local sense towards a naturally defined limit family J=\{J_\varOmega \}_{\varOmega\in \mathcal{G}} as \varepsilon\to 0 . An alternative way of formulating the conclusion is to say that the energy densities (A^\varepsilon\nabla u,\nabla u) \varGamma ‐converge in a distributional sense towards the corresponding limit density. Writing J_\varOmega^\varepsilon in terms of B^\varepsilon=(b_{ij}^\varepsilon) it becomes J_\varOmega^\varepsilon(u) = \int_\varOmega \biggl(\frac{\curpartial u}{\curpartial x_1} + \sum^N_{j=2} b^\varepsilon_{1j} \,\frac{\curpartial u}{\curpartial x_j}\biggr)^2 \frac{1}{b^\varepsilon_{11}}\,\mathrm{d}x+ \sum^N_{i,j=2} \,\int_\varOmega \, \frac{\curpartial u}{\curpartial x_i} \, \frac{\curpartial u}{\curpartial x_j}\, b^\varepsilon_{ij} \,\mathrm{d}x, and the definition of J_\varOmega and the limit density (A\nabla u,\nabla u) is obtained by properly replacing the b^\varepsilon_{ij}\in L_\mathrm{loc}^\infty (\mathbb{R}) by the limit measures b_{ij} and making sense to everything for u in a certain linear subspace of L_\mathrm{loc}^2(\mathbb{R}^N) . Show more

Citation: Asymptotic Analysis, vol. 22, no. 3-4, pp. 261-302, 2000

Authors: Beaulieu, Anne | Hadiji, Rejeb

Article Type: Research Article

Citation: Asymptotic Analysis, vol. 22, no. 3-4, pp. 303-347, 2000

Authors: Eidelman, S. | Kamin, S. | Porper, F.

Article Type: Research Article

Abstract: This paper is devoted to the investigation of classes of uniqueness for classical solutions of the Cauchy problem \begin{eqnarray} && \rho (t,x)\curpartial_{t}u=\sum\limits^{n}_{i,j=1}a_{ij}(t,x)\curpartial_{x_{i}} \curpartial_{x_{j}}u +\sum\limits^{n}_{i=1}b_{i}(t,x)\curpartial_{x_{i}}u+c(t,x)u,\\ && u\vert_{t=0}=u_{0}(x),\quad x\in R^{n} . \end{eqnarray} We study how the behaviour of the function \rho(t,x) as \vert x\vert \to \infty influences the classes of uniqueness of the Cauchy problem. In particular the dependence of such classes on the number of the space coordinates is clarified. We also discuss the sharpness of the obtained results.

Keywords:

Citation: Asymptotic Analysis, vol. 22, no. 3-4, pp. 349-358, 2000