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Introduction to Homogenization [Kõva köide]

(Directeur de Recherche, Centre National de la Recherche Scientifique, University of Paris VI), (Professor, Department of Mathematics, University of Rouen)
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Introduction to HomogenizationSuurem pilt
Teised raamatud teemal:
Püsilink: https://www.kriso.ee/db/9780198565543.html
Märksõnad:
Composite materials are widely used in industry and include such well known examples as superconductors and optical fibers. However, modeling these materials is difficult, since they often has different properties at different points. The mathematical theory of homogenization is designed to handle this problem. The theory uses an idealized homogenous material to model a real composite while taking into account the microscopic structure. This introduction to homogenization theory develops the natural framework of the theory with four chapters on variational methods for partial differential equations. It then discusses the homogenization of several kinds of second-order boundary value problems. It devotes separate chapters to the classical examples of stead and non-steady heat equations, the wave equation, and the linearized system of elasticity. It includes numerous illustrations and examples.

Arvustused

'serve as good textbook for a post-graduate course' ZAMM

Introduction 1(8)
Weak and weak* convergences in Banach spaces
9(17)
Linear forms on Banach spaces
10(2)
Weak convergence
12(4)
Weak* convergence
16(2)
Some properties of Lp-spaces
18(3)
Weak convergenc in Lp for 1 < p < ∞
21(1)
Weak convergence in L1
22(3)
Weak* convergence in L∞
25(1)
Rapidly oscillating periodic functions
26(14)
Periodic functions in L1
26(2)
Examples
28(5)
Weak limits of rapidly oscillating periodic functions
33(7)
Some classes of Sobolev spaces
40(24)
Distributions
40(3)
The spaces W1,p
43(5)
The space H10 and the notion of trace
48(8)
The space H1per
56(3)
Vector-valued spaces of the type Lp (a, b; X)
59(5)
Some variational elliptic problems
64(21)
Bilinear forms on Banach spaces
64(1)
The Lax--Milgram theorem
65(4)
Setting of the variational formulation
69(2)
The Dirichlet problem
71(4)
The Neumann problem
75(3)
The Robin problem
78(3)
Periodic boundary conditions
81(4)
Examples of periodic composite materials
85(22)
Setting of the problem
85(4)
Some physical models
89(6)
The one-dimensional case
95(3)
Layered materials
98(9)
Homogenization of elliptic equations: the convergence result
107(18)
Auxiliary periodic problems
108(4)
The main convergence result
112(3)
The ellipticity of the homogenized matrix
115(5)
Other formulas for the homogenized matrix
120(1)
The one and two-dimensional cases
121(4)
The multiple-scale method
125(13)
The asymptotic expansion
125(8)
Proof of the error estimate
133(5)
Tartar's method of oscillating test functions
138(35)
Proof of the main convergence result
138(4)
Convergence of the energy
142(4)
Correctors
146(6)
Some comparison results
152(5)
Case of weakly converging data
157(7)
Convergence of eigenvalues
164(9)
The two-scale convergence method
173(15)
The general setting
173(3)
Two-scale convergence
176(6)
Proof of the main convergence result
182(3)
A corrector result
185(3)
Homogenization in linearized elasticity
188(15)
Existence and uniqueness
190(4)
Auxiliary periodic problems
194(3)
Homogenization results
197(6)
Homogenization of the heat equation
203(18)
Existence and uniqueness
204(7)
The homogenization result
211(3)
Convergence of the energy
214(2)
A corrector result
216(5)
Homogenization of the wave equation
221(20)
Existence and uniqueness
222(9)
The homogenization result
231(1)
Convergence of the energy
231(7)
A corrector result
238(3)
General approaches to the non-periodic case
241(11)
G-convergence and H-convergence
242(3)
Compensated compactness and correctors
245(3)
Optimal bounds
248(4)
Bibliography 252(6)
Index 258


Doina Cioranescu (Professor, University of Paris VI and CNRS, France) Patrizia Donato (Professor, University of Rouen, France)