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Sensitivity analysis of the Signorini variational inequality

100%

Sokołowski J.

Banach Center Publications

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1987

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tom 19

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nr 1

287-299

2

An elastic membrane with an attached non-linear thermoelastic rod

85%

Horn W., Sokołowski J.

International Journal of Applied Mathematics and Computer Science

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2002

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tom 12

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nr 4

479-486

EN

We study a thermo-mechanical system consisting of an elastic membrane to which a shape-memory rod is glued. The slow movements of the membrane are controlled by the motions of the attached rods. A quasi-static model is used. We include the elastic feedback of the membrane on the rods. This results in investigating an elliptic boundary value problem in a domain Ω ⊂ R^2 with a cut, coupled with non-linear equations for the vertical motions of the rod and the temperature on the rod. We prove the existence of a unique global weak solution to this problem using a fixed point argument.

3

Selfadjoint Extensions for the Elasticity System in Shape Optimization

85%

Nazarov S., Sokołowski J.

Bulletin of the Polish Academy of Sciences. Mathematics

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2004

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tom 52

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nr 3

237-248

EN

Two approaches are proposed to modelling of topological variations in elastic solids. The first approach is based on the theory of selfadjoint extensions of differential operators. In the second approach function spaces with separated asymptotics and point asymptotic conditions are introduced, and a variational formulation is established. For both approaches, accuracy estimates are derived.

4

Shape Sensitivity Analysis of the Dirichlet Laplacian in a Half-Space

68%

Amrouche C., Nečasová Š., Sokołowski J.

Bulletin of the Polish Academy of Sciences. Mathematics

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2004

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tom 52

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nr 4

365-380

EN

Material and shape derivatives for solutions to the Dirichlet Laplacian in a half-space are derived by an application of the speed method. The proposed method is general and can be used for shape sensitivity analysis in unbounded domains for the Neumann Laplacian as well as for the elasticity boundary value problems.

5

A level set method in shape and topology optimization for variational inequalities

68%

Fulmański P., Laurain A., Scheid J.-F., Sokołowski J.

International Journal of Applied Mathematics and Computer Science

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2007

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tom 17

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nr 3

413-430

EN

The level set method is used for shape optimization of the energy functional for the Signorini problem. The boundary variations technique is used in order to derive the shape gradients of the energy functional. The conical differentiability of solutions with respect to the boundary variations is exploited. The topology modifications during the optimization process are identified by means of an asymptotic analysis. The topological derivatives of the energy shape functional are employed for the topology variations in the form of small holes. The derivation of topological derivatives is performed within the framework proposed in (Sokołowski and Żochowski, 2003). Numerical results confirm that the method is efficient and gives better results compared with the classical shape optimization techniques.

6

Self-adjoint extensions of differential operators and exterior topological derivatives in shape optimization

68%

Nazarov S. A., Sokołowski J.

Control and Cybernetics

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2005

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tom 34

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nr 3

903-925

7

On the analysis of boundary value problems in nonsmooth domains

68%

Frémiot G., Horn W., Laurain A., Rao M., Sokołowski J.

Instytut Matematyczny Polskiej Akademii Nauk

EN

Problems involving cracks are of particular importance in structural mechanics, and gave rise to many interesting mathematical techniques to treat them. The difficulties stem from the singularities of domains, which yield lower regularity of solutions. Of particular interest are techniques which allow us to identify cracks and defects from the mechanical properties. Long before advent of mathematical modeling in structural mechanics, defects were identified by the fact that they changed the sound of a piece of material when struck. These techniques have been refined over the years. This volume gives a compilation of recent mathematical methods used in the solution of problems involving cracks, in particular problems of shape optimization. It is based on a collection of recent papers in this area and reflects the work of many authors, namely Gilles Frémiot (Nancy), Werner Horn (Northridge), Jiří Jarušek (Prague), Alexander Khludnev (Novosibirsk), Antoine Laurain (Graz), Murali Rao (Gainesville), Jan Sokołowski (Nancy) and Carol Ann Shubin (Northridge). We review the techniques which can be used for numerical analysis and shape optimization of problems with cracks and of the associated variational inequalities. The mathematical results include sensitivity analysis of variational inequalities, based on the concept of conical differential introduced by Mignot. We complete results on conical differentiability obtained for obstacle problems, by results derived for cracks with non-penetration condition and parabolic variational inequalities. Numerical methods for some problems are given as an illustration. From the point of view of applied mathematics numerical analysis is a necessary ingredient of applicability of the models proposed. We also extend the result on conical differentiability to the case of some evolution variational inequalities. The same mathematical model can be represented in different ways, like primal, dual or mixed formulations for an elliptic problem. We use such possibilities for models with cracks. For the shape sensitivity analysis, in Chapters 1 to 3 we give a thorough introduction to the use of first and second order shape derivatives and their application to problems involving cracks. In Chapter 1, for the convenience of the reader, we provide classical results on shape sensitivity analysis in smooth domains. In Chapter 2, the results on the first order Eulerian semi-derivative in domains with cracks are presented. Of particular interest is the so-called structure theorem for the shape derivative. In Chapter 3, the results on the Fréchet derivative in domains with cracks are presented as well, for first and second order derivatives, using a technique different from that in Chapter 2. In Chapter 4, we extend those ideas to Banach spaces, and give some applications of this extended theory. The polyhedricity of convex sets is considered in the spirit of [71], [87], in the most general setting. These abstract results can be applied to sensitivity analysis of crack problems with non-linear boundary conditions. The results obtained use non-linear potential theory and are interesting on their own. In Chapter 5, several techniques for the study of cracked domains with non-penetration conditions on the crack faces in elastic bodies are presented. The classical crack theory in elasticity is characterized by linear boundary conditions which do not correspond to the physical reality since the crack faces can penetrate each other in this model. In this chapter, non-penetration conditions on the crack faces are considered, which leads to a non-linear problem. The model is presented and the shape sensitivity analysis is performed. Chapter 6 is devoted to the newly developed smooth domain method for cracks. In that chapter the problem on a domain with a crack is transformed into a new problem on a smooth domain. This approach is useful for numerical methods. In \cite{belh} this formulation is used combined with mixed finite elements, and some error estimates are derived for the finite element approximation of variational inequalities with non-linear condition on the crack faces. We give applications of this method to some classical problems. Finally, in Chapter 7 we study integro-differential equations arising from bridged crack models. This is a classical technique, but we introduce a few modern approaches to it for completeness sake.

8

Shape differentiability of the Neumann problem of the Laplace equation in the half-space

60%

Amrouche C., Nečasová Š., Sokołowski J.

Control and Cybernetics

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2008

|

tom 37

|

nr 4

747-769

9

Topological sensitivity analysis for elliptic problems on graphs

51%

Leugering G., Sokołowski J.

Control and Cybernetics

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2008

|

tom 37

|

nr 4

971-997

10

Shape sensitivity analysis of eigenvalues revisited

43%

Nazarov S. A., Sokołowski J.

Control and Cybernetics

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2008

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tom 37

|

nr 4

999-1012

11

A model for passive damping of a membrane

34%

Horn W., Sokołowski J.

Control and Cybernetics

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2005

|

tom 34

|

nr 1

325-337

12

Preface

30%

Hoppe R., Kunisch K., Sokołowski J., Żochowski A.

Control and Cybernetics

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2010

|

tom 39

|

nr 3

593-597

13

Preface to Special Issue

30%

Sokołowski J., Lewiński T.

Control and Cybernetics

|

2005

|

tom 34

|

nr 1

5-6

Ograniczanie wyników

Sensitivity analysis of the Signorini variational inequality

An elastic membrane with an attached non-linear thermoelastic rod

Selfadjoint Extensions for the Elasticity System in Shape Optimization

Shape Sensitivity Analysis of the Dirichlet Laplacian in a Half-Space

A level set method in shape and topology optimization for variational inequalities

Self-adjoint extensions of differential operators and exterior topological derivatives in shape optimization

On the analysis of boundary value problems in nonsmooth domains

Shape differentiability of the Neumann problem of the Laplace equation in the half-space

Topological sensitivity analysis for elliptic problems on graphs

Shape sensitivity analysis of eigenvalues revisited

A model for passive damping of a membrane

Preface

Preface to Special Issue