Your search keyword '"non-concentration"' showing total 5 results

1. Concentration and non-concentration of eigenfunctions of second-order elliptic operators in layered media.

Author

Benabdallah, Assia, Ben-Artzi, Matania, and Dermenjian, Yves

Subjects

ELLIPTIC operators, CARTESIAN coordinates, OPTICAL fibers, DIFFUSION coefficients, ACOUSTICS

Abstract

This work is concerned with operators of the type A = -c A acting in domains fi := fi0 x (0,H) C Rd x Rc The diffusion coefficient c >0 depends on one coordinate y e (0, H) and is bounded but may be discontinuous. This corresponds to the physical model of "layered media," appearing in acoustics, elasticity, optical fibers. Dirichlet boundary conditions are assumed. In general, for each s > 0, the set of eigenfunctions is divided into a disjoint union of three subsets: Fng (non-guided), Fg (guided) and Fres (residual). The residual set shrinks as s ! 0: The customary physical terminology of guided/non-guided is often replaced in the mathematical literature by concentrating/non-concentrating solutions, respectively. For guided waves, the assumption of "layered media" enables us to obtain rigorous estimates of their exponential decay away from concentration zones. The case of non-guided waves has attracted less attention in the literature. While it is not so closely connected to physical models, it leads to some very interesting questions concerning oscillatory solutions and their asymptotic properties. Classical asymptotic methods are available for c (y) e C2 but a lesser degree of regularity excludes such methods. The associated eigenfunctions (in Fng) are oscillatory. However, this fact by itself does not exclude the possibility of "flattening out" of the solution between two consecutive zeros, leading to concentration in the complementary segment. Here we show it cannot happen when c(y) is of bounded variation, by proving a "minimal amplitude hypothesis." However the validity of such results when c(y) is not of bounded variation (even if it is continuous) remains an open problem. [ABSTRACT FROM AUTHOR]

Published

2023

2. CONCENTRATION AND NON-CONCENTRATION OF EIGENFUNCTIONS OF SECOND-ORDER ELLIPTIC OPERATORS IN LAYERED MEDIA

Author

Benabdallah, Assia, Ben-Artzi, Matania, Dermenjian, Yves, Institut de Mathématiques de Marseille (I2M), Aix Marseille Université (AMU)-École Centrale de Marseille (ECM)-Centre National de la Recherche Scientifique (CNRS), Hebrew University (Institute of Mathematics), and Hebrew University

Subjects

58J50 concentration, well of profile, FOS: Physical sciences, eigenfunctions, exponential decay, Mathematics - Spectral Theory, Mathematics - Analysis of PDEs, Secondary 35P20 58J50 concentration non-concentration layered media eigenfunctions second-order elliptic diffusion coefficient piecewise constant bounded variation well of profile exponential decay, [MATH.MATH-MP]Mathematics [math]/Mathematical Physics [math-ph], FOS: Mathematics, bounded variation, 2022. 2010 Mathematics Subject Classification. Primary 35J25, [MATH.MATH-AP]Mathematics [math]/Analysis of PDEs [math.AP], diffusion coefficient, Mathematics - Optimization and Control, Spectral Theory (math.SP), Mathematical Physics, December 10 2022. 2010 Mathematics Subject Classification. Primary 35J25, Mathematical Physics (math-ph), piecewise constant, second-order elliptic, December 10, Secondary 35P20, non-concentration, Optimization and Control (math.OC), [MATH.MATH-OC]Mathematics [math]/Optimization and Control [math.OC], layered media, Analysis of PDEs (math.AP), [MATH.MATH-SP]Mathematics [math]/Spectral Theory [math.SP]

Abstract

This work is concerned with operators of the type A = −c∆ acting in domains Ω := Ω ′ × (0, H) ⊆ R^d × R ^+. The diffusion coefficient c > 0 depends on one coordinate y ∈ (0, H) and is bounded but may be discontinuous. This corresponds to the physical model of "layered media", appearing in acoustics, elasticity, optical fibers... Dirichlet boundary conditions are assumed. In general, for each ε > 0, the set of eigenfunctions is divided into a disjoint union of three subsets : Fng (non-guided), Fg (guided) and Fres (residual). The residual set shrinks as ε → 0. The customary physical terminology of guided/non-guided is often replaced in the mathematical literature by concentrating/non-concentrating solutions, respectively. For guided waves, the assumption of "layered media" enables us to obtain rigorous estimates of their exponential decay away from concentration zones. The case of non-guided waves has attracted less attention in the literature. While it is not so closely connected to physical models, it leads to some very interesting questions concerning oscillatory solutions and their asymptotic properties. Classical asymptotic methods are available for c(y) ∈ C 2 but a lesser degree of regularity excludes such methods. The associated eigenfunctions (in Fng) are oscillatory. However, this fact by itself does not exclude the possibility of "flattening out" of the solution between two consecutive zeros, leading to concentration in the complementary segment. Here we show it cannot happen when c(y) is of bounded variation, by proving a "minimal amplitude hypothesis". However the validity of such results when c(y) is not of bounded variation (even if it is continuous) remains an open problem.; Dans ce papier nous considérons des opérateurs du type A = −c∆ agissant sur des ouverts Ω := Ω ′ × (0, H) ⊆ R^d × R^+, le coefficient de diffusion c > 0 dépendant de la seule coordonnée y ∈ (0, H). Il est borné mais peut être discontinu. Cette situation correspond au modèle physique des "milieux stratifiés" qui intervient en acoustique, en élasticité, dans les fibres optiques, ... Nous supposons la condition de Dirichlet homogène au bord de Ω. Pour chaque ε > 0, nous créons une partition de l'ensemble des fonctions propres en trois sous-ensembles : Fng (fonctions non guidées), Fg (fonctions guidées) et Fres (ensemble résiduel), ce dernier diminuant lorsque ε → 0. La terminologie classique guidée/non guidée est souvent remplacée en mathématiques par les expressions : solutions se concentrant, respectivement ne se concentrant pas. Pour les ondes guidées, le cadre des "milieux stratifiés" nous permet d'obtenir des estimations rigoureuses sur leur décroissance exponentielle loin des zones de concentration. La littérature s'est moins penchée sur le cas des ondes non guidées. Bien que semblant moins intéressante pour les modèles physiques, elle conduit à de très intéressantes questions concernant les solutions oscillantes et leurs propriétés asymptotiques. Des méthodes asymptotiques classiques sont disponibles lorsque (y) ∈ C^2 mais ne marchent pas avec une régularité moindre. Les fonctions de Fng sont oscillantes mais ceci n'exclue pas qu'elles puissent s'aplatir entre deux zéros consécutifs, conduisant à une concentration dans le segment complémentaire. Nous montrons ici que cela ne peut pas arriver quand c(y) est à variation bornée en vérifiant une "hypothèse d'amplitude minimale". Cependant la validité de tels résultats reste un problème ouvert quand c(y) n'est plus à variation bornée, même si ce coefficient est continu.

Published

2022

3. A Non-Concentration Estimate for Partially Rectangular Billiards.

Author

Christianson, Hans

Subjects

*ESTIMATION theory, *MATHEMATICAL domains, *BOUNDARY value problems, *MATHEMATICAL proofs, *STATISTICAL smoothing, *APPROXIMATION theory

Abstract

We consider quasimodes on planar domains with a partially rectangular boundary. We prove that for any ε0 > 0, an 𝒪(λ−ε0) quasimode must haveL2mass in the “wings” (in phase space) bounded below by λ−2−δfor any δ > 0. The proof uses the author's recent work on 0-Gevrey smooth domains to approximate quasimodes onC1, 1domains. There is an improvement forCk, αandC∞domains. [ABSTRACT FROM AUTHOR]

Published

2015

4. Semiclassical non-concentration near hyperbolic orbits

Author

Christianson, Hans

Subjects

*OPERATOR theory, *NUMERICAL solutions to differential equations, *ORBITS (Astronomy), *DIFFERENTIAL geometry

Abstract

Abstract: For a large class of semiclassical pseudodifferential operators, including Schrödinger operators, , on compact Riemannian manifolds, we give logarithmic lower bounds on the mass of eigenfunctions outside neighbourhoods of generic closed hyperbolic orbits. More precisely we show that if A is a pseudodifferential operator which is microlocally equal to the identity near the hyperbolic orbit and microlocally zero away from the orbit, then This generalizes earlier estimates of Colin de Verdière and Parisse [Y. Colin de Verdière, B. Parisse, Équilibre instable en règime semi-classique: I – Concentration microlocale, Comm. Partial Differential Equations 19 (1994) 1535–1563; Équilibre instable en règime semi-classique: II – Conditions de Bohr–Sommerfeld, Ann. Inst. H. Poincaré Phys. Theor. 61 (1994) 347–367] obtained for a special case, and of Burq and Zworski [N. Burq, M. Zworski, Geometric control in the presence of a black box, J. Amer. Math. Soc. 17 (2004) 443–471] for real hyperbolic orbits. [Copyright &y& Elsevier]

Published

2007

5. Semiclassical non-concentration near hyperbolic orbits

Author

Hans Christianson

Subjects

Partial differential equation, Hamiltonian flow, Semiclassical estimates, Hyperbolic trajectory, Loxodromic orbit, Mathematical analysis, Zero (complex analysis), Semiclassical physics, Mathematics::Spectral Theory, Eigenfunction, symbols.namesake, Operator (computer programming), Poincaré conjecture, Complex hyperbolic orbit, symbols, Orbit (control theory), Analysis, Non-concentration, Mathematics, Mathematical physics

Abstract

For a large class of semiclassical pseudodifferential operators, including Schrödinger operators, P(h)=−h2Δg+V(x), on compact Riemannian manifolds, we give logarithmic lower bounds on the mass of eigenfunctions outside neighbourhoods of generic closed hyperbolic orbits. More precisely we show that if A is a pseudodifferential operator which is microlocally equal to the identity near the hyperbolic orbit and microlocally zero away from the orbit, then‖u‖⩽C(log(1/h)/h)‖P(h)u‖+Clog(1/h)‖(I−A)u‖. This generalizes earlier estimates of Colin de Verdière and Parisse [Y. Colin de Verdière, B. Parisse, Équilibre instable en règime semi-classique: I – Concentration microlocale, Comm. Partial Differential Equations 19 (1994) 1535–1563; Équilibre instable en règime semi-classique: II – Conditions de Bohr–Sommerfeld, Ann. Inst. H. Poincaré Phys. Theor. 61 (1994) 347–367] obtained for a special case, and of Burq and Zworski [N. Burq, M. Zworski, Geometric control in the presence of a black box, J. Amer. Math. Soc. 17 (2004) 443–471] for real hyperbolic orbits.

Published

2007