Inverse Autoconvolution Problems with an Application in Laser Physics

Bürger, Steven

21 October 2016

Convolution and, as a special case, autoconvolution of functions are important in many branches of mathematics and have found lots of applications, such as in physics, statistics, image processing and others. While it is a relatively easy task to determine the autoconvolution of a function (at least from the numerical point of view), the inverse problem, which consists in reconstructing a function from its autoconvolution is an ill-posed problem. Hence there is no possibility to solve such an inverse autoconvolution problem with a simple algebraic operation. Instead the problem has to be regularized, which means that it is replaced by a well-posed problem, which is close to the original problem in a certain sense. The outline of this thesis is as follows: In the first chapter we give an introduction to the type of inverse problems we consider, including some basic definitions and some important examples of regularization methods for these problems. At the end of the introduction we shortly present some general results about the convergence theory of Tikhonov-regularization. The second chapter is concerned with the autoconvolution of square integrable functions defined on the interval [0, 1]. This will lead us to the classical autoconvolution problems, where the term “classical” means that no kernel function is involved in the autoconvolution operator. For the data situation we distinguish two cases, namely data on [0, 1] and data on [0, 2]. We present some well-known properties of the classical autoconvolution operators. Moreover, we investigate nonlinearity conditions, which are required to show applicability of certain regularization approaches or which lead convergence rates for the Tikhonov regularization. For the inverse autoconvolution problem with data on the interval [0, 1] we show that a convergence rate cannot be shown using the standard convergence rate theory. If the data are given on the interval [0, 2], we can show a convergence rate for Tikhonov regularization if the exact solution satisfies a sparsity assumption. After these theoretical investigations we present various approaches to solve inverse autoconvolution problems. Here we focus on a discretized Lavrentiev regularization approach, for which even a convergence rate can be shown. Finally, we present numerical examples for the regularization methods we presented. In the third chapter we describe a physical measurement technique, the so-called SD-Spider, which leads to an inverse problem of autoconvolution type. The SD-Spider method is an approach to measure ultrashort laser pulses (laser pulses with time duration in the range of femtoseconds). Therefor we first present some very basic concepts of nonlinear optics and after that we describe the method in detail. Then we show how this approach, starting from the wave equation, leads to a kernel-based equation of autoconvolution type. The aim of chapter four is to investigate the equation and the corresponding problem, which we derived in chapter three. As a generalization of the classical autoconvolution we define the kernel-based autoconvolution operator and show that many properties of the classical autoconvolution operator can also be shown in this new situation. Moreover, we will consider inverse problems with kernel-based autoconvolution operator, which reflect the data situation of the physical problem. It turns out that these inverse problems may be locally well-posed, if all possible data are taken into account and they are locally ill-posed if one special part of the data is not available. Finally, we introduce reconstruction approaches for solving these inverse problems numerically and test them on real and artificial data.

Inverse Probleme

Selbstfaltung

Inverse Problems

Autoconvolution

ddc:518

Angewandte Mathematik

Chemnitz Symposium on Inverse Problems 2014

02 October 2014

Our symposium will bring together experts from the German and international 'Inverse Problems Community' and young scientists. The focus will be on ill-posedness phenomena, regularization theory and practice, and on the analytical, numerical, and stochastic treatment of applied inverse problems in natural sciences, engineering, and finance.

Symposium

inverse Probleme

Chemnitz

symposium

inverse problems

Chemnitz

ddc:518

Mathematik

Symposium

Technische Universität Chemnitz

Inverse Autoconvolution Problems with an Application in Laser Physics

Bürger, Steven

21 September 2016

Convolution and, as a special case, autoconvolution of functions are important in many branches of mathematics and have found lots of applications, such as in physics, statistics, image processing and others. While it is a relatively easy task to determine the autoconvolution of a function (at least from the numerical point of view), the inverse problem, which consists in reconstructing a function from its autoconvolution is an ill-posed problem. Hence there is no possibility to solve such an inverse autoconvolution problem with a simple algebraic operation. Instead the problem has to be regularized, which means that it is replaced by a well-posed problem, which is close to the original problem in a certain sense. The outline of this thesis is as follows: In the first chapter we give an introduction to the type of inverse problems we consider, including some basic definitions and some important examples of regularization methods for these problems. At the end of the introduction we shortly present some general results about the convergence theory of Tikhonov-regularization. The second chapter is concerned with the autoconvolution of square integrable functions defined on the interval [0, 1]. This will lead us to the classical autoconvolution problems, where the term “classical” means that no kernel function is involved in the autoconvolution operator. For the data situation we distinguish two cases, namely data on [0, 1] and data on [0, 2]. We present some well-known properties of the classical autoconvolution operators. Moreover, we investigate nonlinearity conditions, which are required to show applicability of certain regularization approaches or which lead convergence rates for the Tikhonov regularization. For the inverse autoconvolution problem with data on the interval [0, 1] we show that a convergence rate cannot be shown using the standard convergence rate theory. If the data are given on the interval [0, 2], we can show a convergence rate for Tikhonov regularization if the exact solution satisfies a sparsity assumption. After these theoretical investigations we present various approaches to solve inverse autoconvolution problems. Here we focus on a discretized Lavrentiev regularization approach, for which even a convergence rate can be shown. Finally, we present numerical examples for the regularization methods we presented. In the third chapter we describe a physical measurement technique, the so-called SD-Spider, which leads to an inverse problem of autoconvolution type. The SD-Spider method is an approach to measure ultrashort laser pulses (laser pulses with time duration in the range of femtoseconds). Therefor we first present some very basic concepts of nonlinear optics and after that we describe the method in detail. Then we show how this approach, starting from the wave equation, leads to a kernel-based equation of autoconvolution type. The aim of chapter four is to investigate the equation and the corresponding problem, which we derived in chapter three. As a generalization of the classical autoconvolution we define the kernel-based autoconvolution operator and show that many properties of the classical autoconvolution operator can also be shown in this new situation. Moreover, we will consider inverse problems with kernel-based autoconvolution operator, which reflect the data situation of the physical problem. It turns out that these inverse problems may be locally well-posed, if all possible data are taken into account and they are locally ill-posed if one special part of the data is not available. Finally, we introduce reconstruction approaches for solving these inverse problems numerically and test them on real and artificial data.

info:eu-repo/classification/ddc/518

ddc:518

Angewandte Mathematik

Inverse Probleme, Selbstfaltung

Inverse Problems, Autoconvolution

Ermittlung der plastischen Anfangsanisotropie durch Eindringversuche

Lindner, Mario

26 August 2010

Die Genauigkeit der Ergebnisse einer numerischen Simulation von Umformvorgängen wird maßgeblich durch die Beschreibung des Materialverhaltens bestimmt. Neben der Auswahl eines geeigneten Stoffgesetzes zur Darstellung einer Klasse von Werkstoffen ist die Identifikation der in den Modellen enthaltenen Materialparameter zur Charakterisierung seiner besonderen Eigenschaften notwendig. In der vorliegenden Arbeit wird die Bestimmung der Materialparameter eines elastisch-plastischen Deformationsgesetzes zur Beschreibung der plastischen Anisotropie auf Basis der Fließbedingung von Hill unter Berücksichtigung großer Deformationen vorgenommen. Die Ermittlung der Parameter erfolgt durch die Lösung einer nichtlinearen Optimierungsaufgabe (Fehlerquadratminimum) basierend auf dem Vergleich von experimentell durchgeführten Eindringversuchen mit Ergebnissen der numerischen Simulation.

Deformationsgesetz

Hyperelastizität

Orthotropie

Inverse Probleme

Parameteridentikation

hardening

plasticity

ddc:629

Finite-Elemente-Methode

Plastizität

Verfestigung

Anisotropie

Sensitivitätsanalyse

Charakterisierung eines Gebiets durch Spektraldaten eines Dirichletproblems zur Stokesgleichnung / Characterisation of domains by spectral data of a Dirichlet problem for the Stokes equation

Tsiporin, Viktor

20 January 2004

No description available.

Mathematics and Computer Science

inverse Probleme

Stokesgleichung

Faktorisierungsmethode

Integralgleichungen

510 Mathematik

inverse problems

Stokes equation

factorization method

integral equations

31.80

E

Regularization properties of the discrepancy principle for Tikhonov regularization in Banach spaces

Anzengruber, Stephan W., Hofmann, Bernd, Mathé, Peter

11 December 2012

The stable solution of ill-posed non-linear operator equations in Banach space requires regularization. One important approach is based on Tikhonov regularization, in which case a one-parameter family of regularized solutions is obtained. It is crucial to choose the parameter appropriately. Here, a variant of the discrepancy principle is analyzed. In many cases such parameter choice exhibits the feature, called regularization property below, that the chosen parameter tends to zero as the noise tends to zero, but slower than the noise level. Here we shall show such regularization property under two natural assumptions. First, exact penalization must be excluded, and secondly, the discrepancy principle must stop after a finite number of iterations. We conclude this study with a discussion of some consequences for convergence rates obtained by the discrepancy principle under the validity of some kind of variational inequality, a recent tool for the analysis of inverse problems.

inverse Probleme

Tikhonov-Regularisierung

discrepancy principle

parameter choice properties

Inverse problems

Tikhonov-type regularization

ddc:510

inkorrekt gestelltes Problem

Chemnitz Symposium on Inverse Problems 2014

Hofmann, Bernd

January 2014

Our symposium will bring together experts from the German and international 'Inverse Problems Community' and young scientists. The focus will be on ill-posedness phenomena, regularization theory and practice, and on the analytical, numerical, and stochastic treatment of applied inverse problems in natural sciences, engineering, and finance.

info:eu-repo/classification/ddc/518

ddc:518

Symposium, inverse Probleme, Chemnitz

symposium, inverse problems, Chemnitz

Facetten der Konvergenztheorie regularisierter Lösungen im Hilbertraum bei A-priori-Parameterwahl

Schieck, Matthias

22 April 2010

Die vorliegende Arbeit befasst sich mit der Konvergenztheorie für die regularisierten Lösungen inkorrekter inverser Probleme bei A-priori-Parameterwahl im Hilbertraum. Zunächst werden bekannte Konvergenzratenresultate basierend auf verallgemeinerten Quelldarstellungen systematisch zusammengetragen. Danach wird sich mit dem Fall befasst, was getan werden kann, wenn solche Quellbedingungen nicht erfüllt sind. Man gelangt zur Analysis von Abstandsfunktionen, mit deren Hilfe ebenfalls Konvergenzraten ermittelt werden können. Praktisch wird eine solche Abstandsfunktion anhand der Betrachtung einer Fredholmschen Integralgleichung 2. Art abgeschätzt. Schließlich werden die Zusammenhänge zwischen bedingter Stabilität, Stetigkeitsmodul und Konvergenzraten erörtert und durch ein Beispiel zur Laplace-Gleichung untermauert. / This dissertation deals with the convergence theory of regularized solutions of ill-posed inverse problems in Hilbert space with a priori parameter choice. First, well-known convergence rate results based on general source conditions are brought together systematically. Then it is studied what can be done if such source conditions are not fulfilled. One arrives at the analysis of distance functions. With their help, convergence rates can be determined, too. As an example, a distance function is calculated by solving a Fredholm integral equation of the second kind. Finally, the cross-connections between conditional stability, the modulus of continuity and convergence rates is treated accompanied with an example concerning the Laplace equation.

Abstandsfunktion

Ellipsoid

Konvergenzraten

Laplace-Gleichung

Profilfunktion

Qualifizierung

Quelldarstellung

Saturierung

a priori

approximative Quelldarstellung

bedingte Stabilität

lineare inverse Probleme

lineares Regularisierungsschema

ddc:510

Inkorrekt gestelltes Problem

Integralgleichung

Konvergenztheorie

Regularisierungsverfahren

Stetigkeitsmodul

Advanced Methods for Radial Data Sampling in Magnetic Resonance Imaging / Erweiterte Methoden für radiale Datenabtastung bei der Magnetresonanz-Tomographie

Block, Kai Tobias

16 September 2008

No description available.

510 Mathematik

Mathematics and Computer Science

MRT

Kernspintomographie

Bildrekonstruktion

Inverse Probleme

MRI

Image Reconstruction

Inverse Problems

Parallel Imaging

31.76 Numerische Mathematik

EGFZ 050 Applications to physics

Nonlinear Reconstruction Methods for Parallel Magnetic Resonance Imaging / Nichtlineare Rekonstruktionsmethoden für die parallele Magnetresonanztomographie

Uecker, Martin

15 July 2009

No description available.

510 Mathematik

Mathematics and Computer Science

MRT

Kernspintomographie

Bildrekonstruktion

Inverse Probleme

MRI

Image Reconstruction

Inverse Problems

Parallel Imaging

31.76 Numerische Mathematik

EGFZ 050 Applications to physics