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		Revisión de 13:50 22 nov 2007 (ver código fuente)
Cadedif  (Discusión | contribuciones)
← Edición más antigua
		Última versión de 07:37 19 oct 2008 (ver código fuente)
Cadedif  (Discusión | contribuciones) 
 
		
(21 ediciones intermedias no se muestran.)
Línea 1:
Línea 1:
 __NOTOC__  __NOTOC__
  
- Jornada de Dinámica Infinito Dimensional:  Martes 27 de Noviembre de 2007, Departamento de Matemática Aplicada, UCM.   + *<big><u>Jornada de Dinámica Infinito Dimensional</u></big>
- 9:30-13:25 + ::Martes 27 de Noviembre de 2007, Departamento de Matemática Aplicada, UCM. 9:30-13:25, [[Media:jornada_27nov2007_2-3.pdf | [cartel]]]
-   + 
-   + 
  
  
  + <!--
 == Jornada de Dinámica Infinito Dimensional:  Martes 27 de Noviembre de 2007==  == Jornada de Dinámica Infinito Dimensional:  Martes 27 de Noviembre de 2007==
  
Línea 95:
Línea 94:
 continuation after quenching of the solutions. Joint work with A. de  continuation after quenching of the solutions. Joint work with A. de
 Pablo, Mayte Pérez-Llanos, F. Quirós and J. D. Rossi.  Pablo, Mayte Pérez-Llanos, F. Quirós and J. D. Rossi.
-   + -->
- ==iMdea matemáticas:seminario  29 de noviembre 2007 == + 
-   + 
-   + 
- <center> + 
- Dpto. de Matemáticas, sala 520 Facultad de Ciencias -   + 
-   + 
- UAM Ciudad Universitaria de Cantoblanco 28049 Madrid + 
- </center> + 
-   + 
-   + 
- '''10:30 · 11:10 Hardy inequalities in twisted waveguides''' + 
- <center> + 
-   + 
- David KREJ CIRÍK + 
-   + 
- Department of Theoretical Physics, Nuclear Physics Institute,  Academy + 
-   + 
- of Sciences, Rez, Czech Republic e-mail: krejcirik@ujf.cas.cz + 
- </center> + 
-   + 
-   + 
- The Dirichlet Laplacian in tubular domains is a simple but remarkably + 
- successful model for the quantum Hamiltonian in mesoscopic waveguide + 
- systems. We make an overview of geometrically induced Hardy-type + 
- inequalities established recently for the Laplacian in twisted tubes, + 
- and mention consequences for the electronic transport. We begin by + 
- recalling the classical Hardy inequality and its relation to + 
- geometric, spectral, stochastic and other properties of the underlying + 
- Euclidean space. After discussing the complexity of the problem when + 
- reformulated for quasi-cylindrical subdomains, we give a proof of the + 
- Hardy inequality due to a twist of three-dimensional tubes of uniform + 
- cross-section and use it to prove certain stability of the spectrum. + 
- We also discuss similar effects induced by curvature of the ambient + 
- space or switch of boundary conditions. + 
-   + 
- '''11:10 · 11:50 Existence and continuity of global attractors for a + 
- class of non local evolution equations   ''' + 
-   + 
- <center> + 
- Antônio L. PEREIRA + 
-   + 
- Instituto de Matemática e Estatística-USP + 
-   + 
- Rua do Matão, 1010, Cidade Universitária, São Paulo-SP, + 
-   + 
- Brasil  e-mail: alpereir@ime.usp.br + 
- </center> + 
- In this work we prove the existence of a compact global attractor for + 
- the flow of the equation + 
- <center> + 
- <math> + 
- \frac{\partial m(r,t)}{\partial t} = -m(r,t)+g(\beta J*M(r,t)+\beta h) + 
- \qquad h, \beta \geq 0 + 
- </math> + 
- </center> + 
-   + 
- in + 
- <math> + 
- L^{2}(S^{1}). + 
- </math> + 
- We also show that the flow is gradient and the global attractor + 
- depends continuosly on the parameters h and . AMS subject + 
- classification: 34G20,47H15. + 
-   + 
- '''11:50 · 12:10 Coffee break ''' + 
-   + 
-   + 
- '''12:10 · 13:10 Creating materials with desired refraction + 
- coefficient''' + 
- <center> + 
- A. G. RAMM + 
-   + 
- Mathematics Department, Kansas State University, + 
-   + 
- Manhattan, KS 66506-2602, USA + 
-   + 
- ramm@math.ksu.edu + 
- </center> + 
-   + 
- A method is given for calculation of a distribution of small impedance + 
- particles, which should be embedded in a bounded domain, filled with + 
- material with known refraction coefficient, in order that the + 
- resulting new material would have a desired refraction coefficient. + 
- The new material may be created so that it has some desired + 
- wave-focusing properies. For example, it can scatter plane wave mostly + 
- in a fixed solid angle. The inverse scattering problem with scattering + 
- data given at a fixed wave number and at a fixed incident direction is + 
- formulated and solved. + 
-   + 
- [http://www.imdea.org iMdea] + 
Última versión de 07:37 19 oct 2008



Jornada de Dinámica Infinito Dimensional

Martes 27 de Noviembre de 2007, Departamento de Matemática Aplicada, UCM. 9:30-13:25,  [cartel]





Obtenido de "http://euler.quim.ucm.es/wiki/index.php/Workshops"
@@ Línea 1: / Línea 1: @@
 __NOTOC__
-Jornada de Dinámica Infinito Dimensional:  Martes 27 de Noviembre de 2007, Departamento de Matemática Aplicada, UCM.
+*<big><u>Jornada de Dinámica Infinito Dimensional</u></big>
-:30-13:25
+::Martes 27 de Noviembre de 2007, Departamento de Matemática Aplicada, UCM. 9:30-13:25, [[Media:jornada_27nov2007_2-3.pdf | [cartel]]]
+<!--
 == Jornada de Dinámica Infinito Dimensional:  Martes 27 de Noviembre de 2007==
@@ Línea 95: / Línea 94: @@
 continuation after quenching of the solutions. Joint work with A. de
 Pablo, Mayte Pérez-Llanos, F. Quirós and J. D. Rossi.
+-->
-==iMdea matemáticas:seminario  29 de noviembre 2007 ==
-<center>
-Dpto. de Matemáticas, sala 520 Facultad de Ciencias -
-UAM Ciudad Universitaria de Cantoblanco 28049 Madrid
-</center>
-'''10:30 · 11:10 Hardy inequalities in twisted waveguides'''
-<center>
-David KREJ CIRÍK
-Department of Theoretical Physics, Nuclear Physics Institute,  Academy
-of Sciences, Rez, Czech Republic e-mail: krejcirik@ujf.cas.cz
-</center>
-The Dirichlet Laplacian in tubular domains is a simple but remarkably
-successful model for the quantum Hamiltonian in mesoscopic waveguide
-systems. We make an overview of geometrically induced Hardy-type
-inequalities established recently for the Laplacian in twisted tubes,
-and mention consequences for the electronic transport. We begin by
-recalling the classical Hardy inequality and its relation to
-geometric, spectral, stochastic and other properties of the underlying
-Euclidean space. After discussing the complexity of the problem when
-reformulated for quasi-cylindrical subdomains, we give a proof of the
-Hardy inequality due to a twist of three-dimensional tubes of uniform
-cross-section and use it to prove certain stability of the spectrum.
-We also discuss similar effects induced by curvature of the ambient
-space or switch of boundary conditions.
-'''11:10 · 11:50 Existence and continuity of global attractors for a
-class of non local evolution equations   '''
-<center>
-Antônio L. PEREIRA
-Instituto de Matemática e Estatística-USP
-Rua do Matão, 1010, Cidade Universitária, São Paulo-SP,
-Brasil  e-mail: alpereir@ime.usp.br
-</center>
-In this work we prove the existence of a compact global attractor for
-the flow of the equation
-<center>
-<math>
-\frac{\partial m(r,t)}{\partial t} = -m(r,t)+g(\beta J*M(r,t)+\beta h)
-\qquad h, \beta \geq 0
-</math>
-</center>
-in
-<math>
-L^{2}(S^{1}).
-</math>
-We also show that the flow is gradient and the global attractor
-depends continuosly on the parameters h and . AMS subject
-classification: 34G20,47H15.
-'''11:50 · 12:10 Coffee break '''
-'''12:10 · 13:10 Creating materials with desired refraction
-coefficient'''
-<center>
-A. G. RAMM
-Mathematics Department, Kansas State University,
-Manhattan, KS 66506-2602, USA
-ramm@math.ksu.edu
-</center>
-A method is given for calculation of a distribution of small impedance
-particles, which should be embedded in a bounded domain, filled with
-material with known refraction coefficient, in order that the
-resulting new material would have a desired refraction coefficient.
-The new material may be created so that it has some desired
-wave-focusing properies. For example, it can scatter plane wave mostly
-in a fixed solid angle. The inverse scattering problem with scattering
-data given at a fixed wave number and at a fixed incident direction is
-formulated and solved.
-[http://www.imdea.org iMdea]