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＜電子ブック＞
Shape Optimization by the Homogenization Method / by Gregoire Allaire
(Applied Mathematical Sciences. ISSN:2196968X ; 146)

版	1st ed. 2002.
出版者	New York, NY : Springer New York : Imprint: Springer
出版年	2002
本文言語	英語
大きさ	XVI, 458 p : online resource
冊子体	Shape optimization by the homogenization method / Grégoire Allaire
著者標目	*Allaire, Gregoire author SpringerLink (Online service)
件　名	LCSH:Buildings -- Design and construction  全ての件名で検索 LCSH:Engineering mathematics LCSH:Engineering -- Data processing  全ての件名で検索 LCSH:Mathematical analysis LCSH:Mechanics LCSH:Engineering design LCSH:Civil engineering FREE:Building Construction and Design FREE:Mathematical and Computational Engineering Applications FREE:Analysis FREE:Classical Mechanics FREE:Engineering Design FREE:Civil Engineering
一般注記	1 Homogenization -- 1.1 Introduction to Periodic Homogenization -- 1.2 Definition of H-convergence -- 1.3 Proofs and Further Results -- 1.4 Generalization to the Elasticity System -- 2 The Mathematical Modeling of Composite Materials -- 2.1 Homogenized Properties of Composite Materials -- 2.2 Conductivity -- 2.3 Elasticity -- 3 Optimal Design in Conductivity -- 3.1 Setting of Optimal Shape Design -- 3.2 Relaxation by the Homogenization Method -- 4 Optimal Design in Elasticity -- 4.1 Two-phase Optimal Design -- 4.2 Shape Optimization -- 5 Numerical Algorithms -- 5.1 Algorithms for Optimal Design in Conductivity -- 5.2 Algorithms for Structural Optimization The topic of this book is homogenization theory and its applications to optimal design in the conductivity and elasticity settings. Its purpose is to give a self-contained account of homogenization theory and explain how it applies to solving optimal design problems, from both a theoretical and a numerical point of view. The application of greatest practical interest tar­ geted by this book is shape and topology optimization in structural design, where this approach is known as the homogenization method. Shape optimization amounts to finding the optimal shape of a domain that, for example, would be of maximal conductivity or rigidity under some specified loading conditions (possibly with a volume or weight constraint). Such a criterion is embodied by an objective function and is computed through the solution of astate equation that is a partial differential equa­ tion (modeling the conductivity or the elasticity of the structure). Apart from those areas where the loads are applied, the shape boundary is al­ ways assumed to support Neumann boundary conditions (i. e. , isolating or traction-free conditions). In such a setting, shape optimization has a long history and has been studied by many different methods. There is, therefore, a vast literat ure in this field, and we refer the reader to the following short list of books, and references therein [39], [42], [130], [135], [149], [203], [220], [225], [237], [245], [258] Accessibility summary: This PDF is not accessible. It is based on scanned pages and does not support features such as screen reader compatibility or described non-text content (images, graphs etc). However, it likely supports searchable and selectable text based on OCR (Optical Character Recognition). Users with accessibility needs may not be able to use this content effectively. Please contact us at accessibilitysupport@springernature.com if you require assistance or an alternative format Inaccessible, or known limited accessibility No reading system accessibility options actively disabled Publisher contact for further accessibility information: accessibilitysupport@springernature.com HTTP:URL=https://doi.org/10.1007/978-1-4684-9286-6

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