Regularisierungsverfahren zur Rekonstruktion von Aerosolgrößenverteilungen aus LIDAR-Meßdaten

Fischer, Silva.

Unknown Date

Universiẗat, Diss., 2004--Bremen.

Integral equations and resolvents of Toeplitz plus Hankel kernels

January 1981

John N. Tsitsiklis, Bernard C. Levy. / Bibliography: leaves 18-19. / "December, 1981." / "National Science Foundation ... Grant ECS-80-12668"

TK7855.M41 E3845 no.1170

Fredholm equations Numerical solutions

What are, and what are not, Inverse Laplace Transforms

Fordham, Edmund J., Venkataramanan, Lalitha, Mitchell, Jonathan, Valori, Andrea

11 September 2018

Time-domain NMR, in one and higher dimensionalities, makes routine use of inversion algorithms to generate results called \T2-distributions' or joint distributions in two (or higher) dimensions of other NMR parameters, T1, diffusivity D, pore size a, etc. These are frequently referred to as \Inverse Laplace Transforms' although the standard inversion of the Laplace Transform long-established in many textbooks of mathematical physics does not perform (and cannot perform) the calculation of such distributions. The operations performed in the estimation of a \T2-distribution' are the estimation of solutions to a Fredholm Integral Equation (of the First Kind), a different and more general object whose discretization results in a standard problem in linear algebra, albeit suffering from well-known problems of ill-conditioning and computational limits for large problem sizes. The Fredholm Integral Equation is not restricted to exponential kernels; the same solution algorithms can be used with kernels of completely different form. On the other hand, (true) Inverse Laplace Transforms, treated analytically, can be of real utility in solving the diffusion problems highly relevant in the subject of NMR in porous media.

O fluxo espectral de caminhos de operadores de Fredholm auto-adjuntos em espaços de Hilbert / Spectral flow of a path of selfadjoint Fredholm operators in Hilbert spaces

Acevedo, Jeovanny de Jesus Muentes

26 November 2013

O objetivo principal desta dissertação é apresentar o fluxo espectral de um caminho de operadores de Fredholm auto-adjuntos em um espaço de Hilbert e suas propriedades. Pelos resultados clássicos de teoria espectral, sabemos que se H é um espaço de Hilbert e L : H &#8594 H é um operador linear, limitado e auto-adjunto, H pode ser escrito como soma direta ortogonal H+(L)&#8853 H-(L)&#8853 Ker L, onde H+(L) e H-(L) são os subespaços espectrais positivo e negativo de L, respectivamente. No trabalho damos uma definição de fluxo espectral baseada na decomposição acima, aprofundando as conexões deste conceito com a teoria espectral dos operadores de Fredholm em espaços de Hilbert. Entre as propriedades do fluxo espectral, será analisada a invariância homotópica que se apresenta em várias formas. Veremos o conceito de índice de Morse relativo, que estende o clássico índice de Morse, e sua relação com o fluxo espectral. A construção do fluxo espectral dada neste trabalho segue a abordagem de P. M. Fitzpatrick, J. Pejsachowicz e L. Recht em [9]. / The main purpose of this dissertation is to present the spectral flow of a path of selfadjoint Fredholm operators in a Hilbert space and its properties. By classical results in spectral theory, we know that, if H is a Hilbert space and L : H &#8594 H is a bounded self-adjoint linear operator, H may be written as the following orthogonal direct sum H = H+(L)&#8853 H-(L)&#8853 Ker L, where H+(L) and H-(L) are the positive and negative spectral subspaces of L, respectively. In this work we give a definition of spectral flow which is based on the above splitting, examining in depth the connection between this concept and the spectral theory of Fredholm operators in Hilbert spaces. Among the properties of the spectral flow we will analyze the homotopic invariance, which appears on different ways. We will see the concept of relative Morse index, which generalize the classical Morse index, and its relation with the spectral flow. The construction of the spectral flow given in this work follows the approach of P. M. Fitzpatrick, J. Pejsachowicz and L. Recht in [9].

Espaços de Hilbert

Fluxo espectral

Fredholm operators

Hilbert spaces

Índice de Morse

Morse index

Operadores de Fredholm

Spectral flow

Spectral theory.

Teoria espectral.

O fluxo espectral de caminhos de operadores de Fredholm auto-adjuntos em espaços de Hilbert / Spectral flow of a path of selfadjoint Fredholm operators in Hilbert spaces

Jeovanny de Jesus Muentes Acevedo

26 November 2013

O objetivo principal desta dissertação é apresentar o fluxo espectral de um caminho de operadores de Fredholm auto-adjuntos em um espaço de Hilbert e suas propriedades. Pelos resultados clássicos de teoria espectral, sabemos que se H é um espaço de Hilbert e L : H &#8594 H é um operador linear, limitado e auto-adjunto, H pode ser escrito como soma direta ortogonal H+(L)&#8853 H-(L)&#8853 Ker L, onde H+(L) e H-(L) são os subespaços espectrais positivo e negativo de L, respectivamente. No trabalho damos uma definição de fluxo espectral baseada na decomposição acima, aprofundando as conexões deste conceito com a teoria espectral dos operadores de Fredholm em espaços de Hilbert. Entre as propriedades do fluxo espectral, será analisada a invariância homotópica que se apresenta em várias formas. Veremos o conceito de índice de Morse relativo, que estende o clássico índice de Morse, e sua relação com o fluxo espectral. A construção do fluxo espectral dada neste trabalho segue a abordagem de P. M. Fitzpatrick, J. Pejsachowicz e L. Recht em [9]. / The main purpose of this dissertation is to present the spectral flow of a path of selfadjoint Fredholm operators in a Hilbert space and its properties. By classical results in spectral theory, we know that, if H is a Hilbert space and L : H &#8594 H is a bounded self-adjoint linear operator, H may be written as the following orthogonal direct sum H = H+(L)&#8853 H-(L)&#8853 Ker L, where H+(L) and H-(L) are the positive and negative spectral subspaces of L, respectively. In this work we give a definition of spectral flow which is based on the above splitting, examining in depth the connection between this concept and the spectral theory of Fredholm operators in Hilbert spaces. Among the properties of the spectral flow we will analyze the homotopic invariance, which appears on different ways. We will see the concept of relative Morse index, which generalize the classical Morse index, and its relation with the spectral flow. The construction of the spectral flow given in this work follows the approach of P. M. Fitzpatrick, J. Pejsachowicz and L. Recht in [9].

Espaços de Hilbert

Fluxo espectral

Índice de Morse

Operadores de Fredholm

Teoria espectral.

Fredholm operators

Hilbert spaces

Morse index

Spectral flow

Spectral theory.

Asymptotics of the Fredholm determinant corresponding to the first bulk critical universality class in random matrix models

Bothner, Thomas Joachim

06 November 2013

Indiana University-Purdue University Indianapolis (IUPUI) / We study the one-parameter family of determinants $det(I-\gamma K_{PII}),\gamma\in\mathbb{R}$ of an integrable Fredholm operator $K_{PII}$ acting on the interval $(-s,s)$ whose kernel is constructed out of the $\Psi$-function associated with the Hastings-McLeod solution of the second Painlev\'e equation. In case $\gamma=1$, this Fredholm determinant describes the critical behavior of the eigenvalue gap probabilities of a random Hermitian matrix chosen from the Unitary Ensemble in the bulk double scaling limit near a quadratic zero of the limiting mean eigenvalue density. Using the Riemann-Hilbert method, we evaluate the large $s$-asymptotics of $\det(I-\gamma K_)$ for all values of the real parameter $\gamma$.

Fredholm operators -- Research

Linear operators

Riemann-Hilbert problems

Random matrices

Eigenvalues -- Research

Operator theory

Processamento digital de sinais aplicado a análise de distribuição de tempos de relaxação em sinais de ressonância magnética nuclear / Digital signal processing applied to relaxation times distribution analysis in nuclear magnetic resonance signals

Queiroz, Guylherme Emmanuel Tagliaferro de

03 June 2015

Sabe-se que a relaxação de líquidos em meios porosos envolve três mecanismos principais: relaxação bulk, relaxação de superfície e difusão. Muitas vezes, os processos de relaxação de líquidos confinados em meios porosos são dominados pelo processo de relaxação de superfície e difusão do fluído. No chamado regime de difusão rápida, a relaxação de um único poro é comandada por uma função mono exponencial que depende, principalmente, da relação superfície-volume do poro, de modo que em um material poroso, isto é, contendo uma distribuição ampla de tamanho de poros, o sinal de decaimento de magnetização obtido por meio da ressonância magnética nuclear é formado pela soma de exponenciais com diferentes tempos de relaxação. O problema-chave abordado neste trabalho consiste, portanto, em obter por meio desse sinal de magnetização a distribuição dos tempos de relaxação que controlam o decaimento das funções mono-exponenciais. Matematicamente, esse sinal de decaimento de magnetização pode ser descrito na forma geral de uma equação integral de Fredholm do primeiro tipo, cuja solução é um reconhecido problema inverso mal-posto. As abordagens utilizadas na tentativa de solucionar o problema são oriundas de uma área conhecida como processamento digital de sinais, e os seguintes métodos são analisados e comparados neste trabalho: algoritmo dos mínimos quadrados médios com restrição de não negatividade (LMS-NN), algoritmo dos mínimos quadrados médios com restrição de não negatividade e regularizado (LMS-RNN), redes recorrentes de Hopfield e o já bem conhecido na solução de problemas inversos mal-postos, o algoritmo dos mínimos quadrados regularizado (LS-R). Os resultados obtidos no trabalho são bastante positivos, demonstrando que, além do LS-R, existem outras alternativas na solução do problema, que principalmente, permitem atestar as soluções obtidas por qualquer um dos algoritmos. / It is known that the relaxation of liquids in porous media involves three principal mechanisms: bulk relaxation, surface relaxation, and diffusion. Relaxation processes of confined fluids in porous media are often controlled by surface relaxation process and diffusion. In the so-called fast diffusion regime, the relaxation of a single pore is governed by a mono-exponential function that depends primarily on the relation surface-volume of the pore, so that in a porous medium, i.e, in a medium which contains a wide distribution of pore sizes, the signal of magnetization decay obtained by nuclear magnetic resonance is composed by a sum of exponentials controlled by different relaxation times. The main issue discussed in this work consists in obtaining the distribution of relaxation times that controls the decay of the mono-exponential functions that comprise the magnetization signal. Mathematically this signal of magnetization decay can be generally described as a Fredholm integral equation of the first kind, whose solution is a recognized ill-posed inverse problem. The approaches adopted to try to solve the problem come from an area known as digital signal processing, and the following methods analyzed and compared are: non-negative least mean square algorithm (NN-LMS), regularized and nonnegative nleast mean square algorithm (RNN-LMS), recurrent Hopfield networks and regularized least square algorithm (R-LS), acknowledged in the solution of ill-posed inverse problems. The results obtained are very positive, and show that in addition to R-LS there are other alternatives in the solution of the problem, which mainly allow to attest the results achieved through any of the algorithms.

Digital signal processing

Equações integrais de Fredholm

Fredholm integral equations

Meios porosos

Nuclear magnetic ressonance

Porous media

Processamento digital de sinais

Ressonância magnética nuclear

On some Banach Algebra Tools in Operator Theory

Seidel, Markus

13 February 2012

Die vorliegende Arbeit ist der Untersuchung von Operatorfolgen gewidmet, die typischerweise bei der Anwendung von Approximationsverfahren auf stetige lineare Operatoren entstehen. Dabei stehen die Stabilität der Folgen sowie das asymptotische Verhalten gewisser Charakteristika wie Normen, Konditionszahlen, Fredholmeigenschaften und Pseudospektren im Mittelpunkt. Das Hauptaugenmerk liegt auf der Entwicklung der Theorie für Operatoren auf Banachräumen. Hierbei bildet ein dafür geeigneter Konvergenzbegriff, die sogenannte P-starke Konvergenz, den Ausgangspunkt, welcher das Studium der gewünschten Eigenschaften in einer erstaunlichen Allgemeinheit gestattet. Die erzielten Resultate kommen, neben einer Reihe weiterer Anwendungen, insbesondere für das Projektionsverfahren für banddominierte Operatoren zum Einsatz.

approximative Projektion

banddominierter Operator

approximate projection

Fredholm theory

spectral approximation

band-dominated operator

finite section method

ddc:510

Fredholm-Theorie

Spektrum <Mathematik>

Projektionsverfahren

Bandmatrix

Semiclassical approximations for single eigenstates of quantum maps / Semiklassische Näherungen für einzelne Eigenzustände von Quantenabbildungen

Sczyrba, Martin

23 March 2003

In der vorliegenden Arbeit wird die Fredholm-Methode zur semiklassischen Berechnung einzelner Eigenzustaende von Quantenabbildungen eingesetzt. Es wird gezeigt, wie auch Eigenzustaende zu entarteten Eigenwerten berechnet werden koennen. Die semiklassische Berechnung eines Eigenzustandes erfolgt mittels der Husimifunktion. Es wird gezeigt, wie das Auftreten von Bifurkationen periodischer Bahnen beruecksichtigt werden kann. Dies geschieht auch fuer den Fall von energiegemittelten Eigenzustaenden. Ebenfalls wird die Stoerung einer Quantenabbildung durch einen Punktstreuer und dessen Auswirkungen auf die semiklassische Berechnungen untersucht.

Bifurkation

Eigenzustand

Fredholm-Methode

Punktstreuer

Semiklassik

Fredholm´s method

bifurcation

eigenstate

point-like scatterer

semiclassics

ddc:29

rvk:UK 4000

Approximationstheorie

Halbklassische Approximation

Quantenmechanik

Quantenzustand

Quasiklassische Näherung

Processamento digital de sinais aplicado a análise de distribuição de tempos de relaxação em sinais de ressonância magnética nuclear / Digital signal processing applied to relaxation times distribution analysis in nuclear magnetic resonance signals

Guylherme Emmanuel Tagliaferro de Queiroz

03 June 2015

Sabe-se que a relaxa&ccedil;&atilde;o de l&iacute;quidos em meios porosos envolve tr&ecirc;s mecanismos principais: relaxa&ccedil;&atilde;o bulk, relaxa&ccedil;&atilde;o de superf&iacute;cie e difus&atilde;o. Muitas vezes, os processos de relaxa&ccedil;&atilde;o de l&iacute;quidos confinados em meios porosos s&atilde;o dominados pelo processo de relaxa&ccedil;&atilde;o de superf&iacute;cie e difus&atilde;o do flu&iacute;do. No chamado regime de difus&atilde;o r&aacute;pida, a relaxa&ccedil;&atilde;o de um &uacute;nico poro &eacute; comandada por uma fun&ccedil;&atilde;o mono exponencial que depende, principalmente, da rela&ccedil;&atilde;o superf&iacute;cie-volume do poro, de modo que em um material poroso, isto &eacute;, contendo uma distribui&ccedil;&atilde;o ampla de tamanho de poros, o sinal de decaimento de magnetiza&ccedil;&atilde;o obtido por meio da resson&acirc;ncia magn&eacute;tica nuclear &eacute; formado pela soma de exponenciais com diferentes tempos de relaxa&ccedil;&atilde;o. O problema-chave abordado neste trabalho consiste, portanto, em obter por meio desse sinal de magnetiza&ccedil;&atilde;o a distribui&ccedil;&atilde;o dos tempos de relaxa&ccedil;&atilde;o que controlam o decaimento das fun&ccedil;&otilde;es mono-exponenciais. Matematicamente, esse sinal de decaimento de magnetiza&ccedil;&atilde;o pode ser descrito na forma geral de uma equa&ccedil;&atilde;o integral de Fredholm do primeiro tipo, cuja solu&ccedil;&atilde;o &eacute; um reconhecido problema inverso mal-posto. As abordagens utilizadas na tentativa de solucionar o problema s&atilde;o oriundas de uma &aacute;rea conhecida como processamento digital de sinais, e os seguintes m&eacute;todos s&atilde;o analisados e comparados neste trabalho: algoritmo dos m&iacute;nimos quadrados m&eacute;dios com restri&ccedil;&atilde;o de n&atilde;o negatividade (LMS-NN), algoritmo dos m&iacute;nimos quadrados m&eacute;dios com restri&ccedil;&atilde;o de n&atilde;o negatividade e regularizado (LMS-RNN), redes recorrentes de Hopfield e o j&aacute; bem conhecido na solu&ccedil;&atilde;o de problemas inversos mal-postos, o algoritmo dos m&iacute;nimos quadrados regularizado (LS-R). Os resultados obtidos no trabalho s&atilde;o bastante positivos, demonstrando que, al&eacute;m do LS-R, existem outras alternativas na solu&ccedil;&atilde;o do problema, que principalmente, permitem atestar as solu&ccedil;&otilde;es obtidas por qualquer um dos algoritmos. / It is known that the relaxation of liquids in porous media involves three principal mechanisms: bulk relaxation, surface relaxation, and diffusion. Relaxation processes of confined fluids in porous media are often controlled by surface relaxation process and diffusion. In the so-called fast diffusion regime, the relaxation of a single pore is governed by a mono-exponential function that depends primarily on the relation surface-volume of the pore, so that in a porous medium, i.e, in a medium which contains a wide distribution of pore sizes, the signal of magnetization decay obtained by nuclear magnetic resonance is composed by a sum of exponentials controlled by different relaxation times. The main issue discussed in this work consists in obtaining the distribution of relaxation times that controls the decay of the mono-exponential functions that comprise the magnetization signal. Mathematically this signal of magnetization decay can be generally described as a Fredholm integral equation of the first kind, whose solution is a recognized ill-posed inverse problem. The approaches adopted to try to solve the problem come from an area known as digital signal processing, and the following methods analyzed and compared are: non-negative least mean square algorithm (NN-LMS), regularized and nonnegative nleast mean square algorithm (RNN-LMS), recurrent Hopfield networks and regularized least square algorithm (R-LS), acknowledged in the solution of ill-posed inverse problems. The results obtained are very positive, and show that in addition to R-LS there are other alternatives in the solution of the problem, which mainly allow to attest the results achieved through any of the algorithms.

Equações integrais de Fredholm

Meios porosos

Processamento digital de sinais

Ressonância magnética nuclear

Digital signal processing

Fredholm integral equations

Nuclear magnetic ressonance

Porous media