nach oben

1987 | Buch

Kapitel lesen Erstes Kapitel lesen

Elliptic Differential Equations and Obstacle Problems

verfasst von: Giovanni Maria Troianiello

Verlag: Springer US

Buchreihe : The University Series in Mathematics

Enthalten in: Professional Book Archive

Einloggen, um Zugang zu erhalten

Über dieses Buch

In the few years since their appearance in the mid-sixties, variational inequalities have developed to such an extent and so thoroughly that they may now be considered an "institutional" development of the theory of differential equations (with appreciable feedback as will be shown). This book was written in the light of these considerations both in regard to the choice of topics and to their treatment. In short, roughly speaking my intention was to write a book on second-order elliptic operators, with the first half of the book, as might be expected, dedicated to function spaces and to linear theory whereas the second, nonlinear half would deal with variational inequalities and non variational obstacle problems, rather than, for example, with quasilinear or fully nonlinear equations (with a few exceptions to which I shall return later). This approach has led me to omit any mention of "physical" motivations in the wide sense of the term, in spite of their historical and continuing importance in the development of variational inequalities. I here addressed myself to a potential reader more or less aware of the significant role of variational inequalities in numerous fields of applied mathematics who could use an analytic presentation of the fundamental theory, which would be as general and self-contained as possible.

Inhaltsverzeichnis

Frontmatter

1. Function Spaces

Abstract

In the modern approach to partial differential equations a pivotal role is played by various function spaces which are defined in terms of the existence of derivatives (either in the classical or in a generalized, weaker sense). In this chapter we develop the study of such spaces to the extent required for the investigation of second-order elliptic problems.

Giovanni Maria Troianiello

2. The Variational Theory of Elliptic Boundary Value Problems

Abstract

Consider the following “model problem”:

$$\begin{gathered} - \Delta u + u = f\quad in\;Q, \hfill \\ u = 0\quad on\;\partial \Omega \backslash \Gamma ,\quad \left( {\nabla u} \right) \cdot v = 0\quad on\quad \Gamma , \hfill \\ \end{gathered}$$

(2.1)

where ∆ denotes, as is usual in the literature, the Laplacian $\sum\nolimits_{{i = 1}}^{N} {{\partial _{2}}} /\partial x_{i}^{2} $, and f is an arbitrarily fixed function from L ²(Ω). (As stipulated in the Glossary of Basic Notations, Ω is from now on supposed to be a bounded domain.) Let ∂Ω be of class C ¹ and let its open portion Γ be closed as well. With the help of Section 1.7.3 for what concerns boundary values, we see that (2.1) certainly makes sense in the function space H ²(Ω) and implies

$$\begin{gathered} u \in H_{0}^{1}\left( {\Omega \cup \Gamma } \right), \hfill \\ a\left( {u,v} \right) \equiv \int_{\Omega } {\left( {{u_{{{x_{i}}}}}{v_{{{x_{i}}}}} + uv} \right)dx = \int_{\Omega } {fvdx\quad for\;v \in H_{0}^{1}\left( {\Omega \cup \Gamma } \right)} } \hfill \\ \end{gathered} $$

(2.2)

by the divergence theorem: see Theorem 1.53. (From now on we adopt the summation convention: repeated dummy indices indicate summation from 1 to N.)

Giovanni Maria Troianiello

3. H k,p and C k,δ Theory

Abstract

The contents of the present chapter can be tersely illustrated by considering the mixed elliptic b.v.p.

$$\begin{gathered} - {\left( {{a^{{ij}}}{u_{{{x_{i}}}}} + {d^{j}}u} \right)_{{{x_{j}}}}} + {b_{j}}{u_{{{x_{i}}}}} + cu = f\quad in\;Q, \hfill \\ u = 0\quad on\;\partial \Omega \backslash \Gamma ,\quad \left( {{a^{{ij}}}{u_{{{x_{i}}}}} + {d^{j}}u} \right)\left| {_{{{\Gamma ^{{{v^{j}}}}}}}} \right. = 0\quad on\;\Gamma \hfill \\ \end{gathered} $$

Giovanni Maria Troianiello

4. Variational Inequalities

Abstract

The minimum problem we mentioned in the introduction to Chapter 2 can be generalized as follows:

$$\begin{gathered} \min imize\quad F\left( v \right) \equiv \frac{1}{2}\int_{\Omega } {\left( {{{\left| {\Delta v} \right|}^{2}} + {v^{2}}} \right)} dx - \int_{\Omega } {fvdx} \hfill \\ over\;a\;convex\;subset\;K\;of\;H_{0}^{1}\left( {\Omega \cup \Gamma } \right) \hfill \\ \end{gathered} $$

[with f ∈ L ² (Ω), Γ of class C ¹]. If u is a solution to this problem, for any choice of v in 𝕂 the function ℱ(u + λ(v — u)) of λ ∈ [0, 1] must attain its minimum at λ = 0; hence, u must satisfy the condition

$$u \in K,\quad \frac{d}{{d\lambda }}F\left( {u + \lambda \left( {v - u} \right)} \right)\left| {_{{\lambda = 0}} \geqslant 0\quad for\;v \in K,} \right. $$

which amounts to

$$u \in K,\quad a\left( {u,v - u} \right) \geqslant \int_{\Omega } {f\left( {v - u} \right)} dx\quad for\;v \in K $$

(4.1)

[where a(u, v) denotes the symmetric bilinear form (math)]. Vice versa, a solution of (4.1) necessarily minimizes ℱ(v) over 𝕂 (see Lemma 4.1 below). These simple observations are sufficient to introduce the content of the present chapter.

Giovanni Maria Troianiello

5. Nonvariational Obstacle Problems

Abstract

The first section in this chapter is based on the following considerations. Obstacle problems such as (4.44) and (4.48) can be formulated even when the operator L is of the nonvariational type; candidates as solutions are those functions u whose first and second derivatives are defined a.e. in Ω, so that Lu certainly makes sense. We can still avail ourselves of existence, uniqueness, and regularity results for v.i.’s if the leading coefficients of L are smooth. If not, we can approximate L by a sequence of operators to which variational tools do apply.

Giovanni Maria Troianiello

Backmatter

Titel: Elliptic Differential Equations and Obstacle Problems
verfasst von: Giovanni Maria Troianiello
Verlag: Springer US
Electronic ISBN: 978-1-4899-3614-1
Print ISBN: 978-1-4899-3616-5
DOI: https://doi.org/10.1007/978-1-4899-3614-1

Springer Professional

Über dieses Buch

Inhaltsverzeichnis

Frontmatter

1. Function Spaces

2. The Variational Theory of Elliptic Boundary Value Problems

3. H k,p and C k,δ Theory

4. Variational Inequalities

5. Nonvariational Obstacle Problems

Backmatter