Spelling suggestions: "subject:"elliptische differentialgleichung"" "subject:"elliptische differentialgleichungs""
31 |
Control constrained optimal control problems in non-convex three dimensional polyhedral domainsWinkler, Gunter 28 May 2008 (has links) (PDF)
The work selects a specific issue from the numerical analysis of
optimal control problems. We investigate a linear-quadratic optimal
control problem based on a partial differential equation on
3-dimensional non-convex domains. Based on efficient solution methods
for the partial differential equation an algorithm known from control
theory is applied. Now the main objectives are to prove that there is
no degradation in efficiency and to verify the result by numerical
experiments.
We describe a solution method which has second order convergence,
although the intermediate control approximations are piecewise
constant functions. This superconvergence property is gained from a
special projection operator which generates a piecewise constant
approximation that has a supercloseness property, from a sufficiently
graded mesh which compensates the singularities introduced by the
non-convex domain, and from a discretization condition which
eliminates some pathological cases.
Both isotropic and anisotropic discretizations are investigated and
similar superconvergence properties are proven.
A model problem is presented and important results from the regularity
theory of solutions to partial differential equation in non-convex
domains have been collected in the first chapters. Then a collection
of statements from the finite element analysis and corresponding
numerical solution strategies is given. Here we show newly developed
tools regarding error estimates and projections into finite element
spaces. These tools are necessary to achieve the main results. Known
fundamental statements from control theory are applied to the given
model problems and certain conditions on the discretization are
defined. Then we describe the implementation used to solve the model
problems and present all computed results.
|
32 |
Identification of material parameters in mechanical modelsMeyer, Marcus 04 June 2010 (has links) (PDF)
Die Dissertation beschäftigt sich mit
Parameteridentifikationsproblemen, wie sie häufig in
Fragestellungen der Festkörpermechanik zu finden sind. Hierbei
betrachten wir die Identifikation von Materialparametern -- die
typischerweise die Eigenschaften der zugrundeliegenden
Materialien repräsentieren -- aus gemessenen Verformungen oder
Belastungen eines Testkörpers. In mathematischem Sinne
entspricht dies der Lösung von Identifikationsproblemen, die
eine spezielle Klasse von inversen Problemen bilden.
Der Inhalt der Dissertation ist folgendermaßen gegliedert. Nach
dem einführenden Abschnitt 1 wird in Abschnitt 2 ein Überblick
von Optimierungs- und Regularisierungsverfahren zur stabilen
Lösung nichtlinearer inverser Probleme diskutiert. In Abschnitt
3 betrachten wir die Identifikation von skalaren und stückweise
konstanten Parametern in linearen elliptischen
Differentialgleichungen. Hierbei werden zwei Testprobleme
erörtert, die Identifikation von Diffusions- und
Reaktionsparameter in einer allgemeinen elliptischen
Differentialgleichung und die Identifikation der
Lame-Konstanten in einem Modell der linearisierten Elastizität.
Die zugrunde liegenden PDE-Modelle und Lösungszugänge werden
erläutert. Insbesondere betrachten wir hier Newton-artige
Algorithmen, Gradientenmethoden, Multi-Parameter
Regularisierung and den evolutionären Algorithmus CMAES.
Abschließend werden Ergebnisse einer numerischen Studie
präsentiert. Im Abschnitt 4 konzentrieren wir uns auf die
Identifikation von verteilten Parametern in hyperelastischen
Materialmodellen. Das nichtlineare Elastizitätsproblem wird
detailiert erläutert und verschiedene Materialmodelle werden
diskutiert (linear elastisches St.-Venant-Kirchhoff Material
und nichtlineare Neo-Hooke, Mooney-Rivlin und Modified-Fung
Materialien. Zur Lösung des resultierenden
Parameteridentifikationsproblems werden Lösungsansätze aus der
optimalen Steuerung in Form eines Newton-Lagrange SQP
Algorithmus verwendet. Die Resultate einer numerischen Studie
werden präsentiert, basierend auf einem zweidimensionales
Testproblem mit einer sogenannten Cook-Mebran. Abschließend
wird im Abschnitt 5 die Verwendung adaptiver FEM für die Lösung
von Parameteridentifikationsproblems kurz erörtert. / The dissertation is focussed on parameter identification
problems arising in the context of structural mechanics. At
this, we consider the identification of material parameters -
which typically represent the properties of an underlying
material - from given measured displacements and forces of a
loaded test body. In mathematical terms such problems denote
identification problems as a special case of general inverse
problems.
The dissertation is organized as follows. After the
introductive section 1, section 2 is devoted to a survey of
optimization and regularization methods for the stable solution
of nonlinear inverse problems. In section 3 we consider the
identification of scalar and piecewise constant parameters in
linear elliptic differential equations and examine two test
problems, namely the identification of diffusion and reaction
parameters in a generalized linear elliptic differential
equation of second order and the identification of the Lame
constants in the linearized elasticity model. The underlying
PDE models are introduced and solution approaches are discussed
in detail. At this, we consider Newton-type algorithms,
gradient methods, multi-parameter regularization, and the
evolutionary algorithm CMAES. Consequently, numerical studies
for a two-dimensional test problem are presented. In section 4
we point out the identification of distributed material
parameters in hyperelastic deformation models. The nonlinear
elasticity boundary value problem for large deformations is
introduced. We discuss several material laws for linear elastic
(St.-Venant-Kirchhoff) materials and nonlinear Neo-Hooke,
Mooney-Rivlin, and Modified-Fung materials. For the solution of
the corresponding parameter identification problem, we focus on
an optimal control solution approach and introduce a
regularized Newton-Lagrange SQP method. The Newton-Lagrange
algorithm is demonstrated within a numerical study. Therefore,
a simplified two-dimensional Cook membrane test problem is
solved. Additionally, in section 5 the application of adaptive
methods for the solution of parameter identification problems
is discussed briefly.
|
33 |
Control constrained optimal control problems in non-convex three dimensional polyhedral domainsWinkler, Gunter 20 March 2008 (has links)
The work selects a specific issue from the numerical analysis of
optimal control problems. We investigate a linear-quadratic optimal
control problem based on a partial differential equation on
3-dimensional non-convex domains. Based on efficient solution methods
for the partial differential equation an algorithm known from control
theory is applied. Now the main objectives are to prove that there is
no degradation in efficiency and to verify the result by numerical
experiments.
We describe a solution method which has second order convergence,
although the intermediate control approximations are piecewise
constant functions. This superconvergence property is gained from a
special projection operator which generates a piecewise constant
approximation that has a supercloseness property, from a sufficiently
graded mesh which compensates the singularities introduced by the
non-convex domain, and from a discretization condition which
eliminates some pathological cases.
Both isotropic and anisotropic discretizations are investigated and
similar superconvergence properties are proven.
A model problem is presented and important results from the regularity
theory of solutions to partial differential equation in non-convex
domains have been collected in the first chapters. Then a collection
of statements from the finite element analysis and corresponding
numerical solution strategies is given. Here we show newly developed
tools regarding error estimates and projections into finite element
spaces. These tools are necessary to achieve the main results. Known
fundamental statements from control theory are applied to the given
model problems and certain conditions on the discretization are
defined. Then we describe the implementation used to solve the model
problems and present all computed results.
|
34 |
Identification of material parameters in mechanical modelsMeyer, Marcus 04 June 2010 (has links)
Die Dissertation beschäftigt sich mit
Parameteridentifikationsproblemen, wie sie häufig in
Fragestellungen der Festkörpermechanik zu finden sind. Hierbei
betrachten wir die Identifikation von Materialparametern -- die
typischerweise die Eigenschaften der zugrundeliegenden
Materialien repräsentieren -- aus gemessenen Verformungen oder
Belastungen eines Testkörpers. In mathematischem Sinne
entspricht dies der Lösung von Identifikationsproblemen, die
eine spezielle Klasse von inversen Problemen bilden.
Der Inhalt der Dissertation ist folgendermaßen gegliedert. Nach
dem einführenden Abschnitt 1 wird in Abschnitt 2 ein Überblick
von Optimierungs- und Regularisierungsverfahren zur stabilen
Lösung nichtlinearer inverser Probleme diskutiert. In Abschnitt
3 betrachten wir die Identifikation von skalaren und stückweise
konstanten Parametern in linearen elliptischen
Differentialgleichungen. Hierbei werden zwei Testprobleme
erörtert, die Identifikation von Diffusions- und
Reaktionsparameter in einer allgemeinen elliptischen
Differentialgleichung und die Identifikation der
Lame-Konstanten in einem Modell der linearisierten Elastizität.
Die zugrunde liegenden PDE-Modelle und Lösungszugänge werden
erläutert. Insbesondere betrachten wir hier Newton-artige
Algorithmen, Gradientenmethoden, Multi-Parameter
Regularisierung and den evolutionären Algorithmus CMAES.
Abschließend werden Ergebnisse einer numerischen Studie
präsentiert. Im Abschnitt 4 konzentrieren wir uns auf die
Identifikation von verteilten Parametern in hyperelastischen
Materialmodellen. Das nichtlineare Elastizitätsproblem wird
detailiert erläutert und verschiedene Materialmodelle werden
diskutiert (linear elastisches St.-Venant-Kirchhoff Material
und nichtlineare Neo-Hooke, Mooney-Rivlin und Modified-Fung
Materialien. Zur Lösung des resultierenden
Parameteridentifikationsproblems werden Lösungsansätze aus der
optimalen Steuerung in Form eines Newton-Lagrange SQP
Algorithmus verwendet. Die Resultate einer numerischen Studie
werden präsentiert, basierend auf einem zweidimensionales
Testproblem mit einer sogenannten Cook-Mebran. Abschließend
wird im Abschnitt 5 die Verwendung adaptiver FEM für die Lösung
von Parameteridentifikationsproblems kurz erörtert. / The dissertation is focussed on parameter identification
problems arising in the context of structural mechanics. At
this, we consider the identification of material parameters -
which typically represent the properties of an underlying
material - from given measured displacements and forces of a
loaded test body. In mathematical terms such problems denote
identification problems as a special case of general inverse
problems.
The dissertation is organized as follows. After the
introductive section 1, section 2 is devoted to a survey of
optimization and regularization methods for the stable solution
of nonlinear inverse problems. In section 3 we consider the
identification of scalar and piecewise constant parameters in
linear elliptic differential equations and examine two test
problems, namely the identification of diffusion and reaction
parameters in a generalized linear elliptic differential
equation of second order and the identification of the Lame
constants in the linearized elasticity model. The underlying
PDE models are introduced and solution approaches are discussed
in detail. At this, we consider Newton-type algorithms,
gradient methods, multi-parameter regularization, and the
evolutionary algorithm CMAES. Consequently, numerical studies
for a two-dimensional test problem are presented. In section 4
we point out the identification of distributed material
parameters in hyperelastic deformation models. The nonlinear
elasticity boundary value problem for large deformations is
introduced. We discuss several material laws for linear elastic
(St.-Venant-Kirchhoff) materials and nonlinear Neo-Hooke,
Mooney-Rivlin, and Modified-Fung materials. For the solution of
the corresponding parameter identification problem, we focus on
an optimal control solution approach and introduce a
regularized Newton-Lagrange SQP method. The Newton-Lagrange
algorithm is demonstrated within a numerical study. Therefore,
a simplified two-dimensional Cook membrane test problem is
solved. Additionally, in section 5 the application of adaptive
methods for the solution of parameter identification problems
is discussed briefly.
|
Page generated in 0.1249 seconds