Preface to the Classics Edition

p. xv

Preface

p. xix

General plan and interdependence table

p. xxvi

Elliptic boundary value problems

p. 1

Introduction

p. 1

Abstract problems

p. 2

The symmetric case. Variational inequalities

p. 2

The nonsymmetric case. The Lax-Milgram lemma

p. 7

Exercises

p. 9

Examples of elliptic boundary value problems

p. 10

The Sobolev spaces H[superscript m] ([Omega]). Green's formulas

p. 10

First examples of second-order boundary value problems

p. 15

The elasticity problem

p. 23

Examples of fourth-order problems: The biharmonic problem, the plate problem

p. 28

Exercises

p. 32

Bibliography and Comments

p. 35

Introduction to the finite element method

p. 36

Introduction

p. 36

Basic aspects of the finite element method

p. 37

The Galerkin and Ritz methods

p. 37

The three basic aspects of the finite element method. Conforming finite element methods

p. 38

Exercises

p. 43

Examples of finite elements and finite element spaces

p. 43

Requirements for finite element spaces

p. 43

First examples of finite elements for second order problems: n-Simplices of type (k), (3')

p. 44

Assembly in triangulations. The associated finite element spaces

p. 51

n-Rectangles of type (k). Rectangles of type (2'), (3'). Assembly in triangulations

p. 55

First examples of finite elements with derivatives as degrees of freedom: Hermite n-simplices of type (3), (3'). Assembly in triangulations

p. 64

First examples of finite elements for fourth-order problems: the Argyris and Bell triangles, the Bogner-Fox-Schmit rectangle. Assembly in triangulations

p. 69

Exercises

p. 77

General properties of finite elements and finite element spaces

p. 78

Finite elements as triples (K, P, [Sigma]). Basic definitions. The P-interpolation operator

p. 78

Affine families of finite elements

p. 82

Construction of finite element spaces X[subscript h]. Basic definitions. The X[subscript h]-interpolation operator

p. 88

Finite elements of class l[superscript 0] and l[superscript 1]

p. 95

Taking into account boundary conditions. The spaces X[subscript 0h] and X[subscript 00h]

p. 96

Final comments

p. 99

Exercises

p. 101

General considerations on convergence

p. 103

Convergent family of discrete problems

p. 103

Cea's lemma. First consequences. Orders of convergence

p. 104

Bibliography and comments

p. 106

Conforming finite element methods for second order problems

p. 110

Introduction

p. 110

Interpolation theory in Sobolev spaces

p. 112

The Sobolev spaces W[superscript m,p]([Omega]). The quotient space W[superscript k+1,p]([Omega])/P[subscript k]([Omega])

p. 112

Error estimates for polynomial preserving operators

p. 116

Estimates of the interpolation errors v - [Pi subscript K]v [subscript m,q,K] for affine families of finite elements

p. 122

Exercises

p. 126

Application to second-order problems over polygonal domains

p. 131

Estimate of the error [double vertical line]u - u[subscript h double vertical line subscript 1,[Omega]

p. 131

Sufficient conditions for lim[subscript h[right arrow]0 double vertical line]u u[subscript h double vertical line subscript 1,[Omega] = 0

p. 134

Estimate of the error

p. 136

Concluding remarks. Inverse inequalities

p. 139

Exercises

p. 143

Uniform convergence

p. 147

A model problem. Weighted semi-norms . [subscript [phi],m,[Omega]

p. 147

Uniform boundedness of the mapping u [right arrow] u[subscript h] with respect to appropriate weighted norms

p. 155

Estimates of the errors

p. 163

Exercises

p. 167

Bibliography and comments

p. 168

Other finite element methods for second-order problems

p. 174

Introduction

p. 174

The effect of numerical integration

p. 178

Taking into account numerical integration. Description of the resulting discrete problem

p. 178

Abstract error estimate: The first Strang lemma

p. 185

Sufficient conditions for uniform V[subscript h]-ellipticity

p. 187

Consistency error estimates. The Bramble-Hilbert lemma

p. 190

Estimate of the error [double vertical line]u - u[subscript h double vertical line subscript 1,[Omega]

p. 199

Exercises

p. 201

A nonconforming method

p. 207

Nonconforming methods for second-order problems. Description of the resulting discrete problem

p. 207

Abstract error estimate: The second Strang lemma

p. 209

An example of a nonconforming finite element: Wilson's brick

p. 211

Consistency error estimate. The bilinear lemma

p. 217

Estimate of the error ([Sigma subscript K[set membership]t subscript h]

p. 220

Exercises

p. 223

Isoparametric finite elements

p. 224

Isoparametric families of finite elements

p. 224

Examples of isoparametric finite elements

p. 227

Estimates of the interpolation errors v - [Pi subscript K]v [subscript m,q,K]

p. 230

Exercises

p. 243

Application to second order problems over curved domains

p. 248

Approximation of a curved boundary with isoparametric finite elements

p. 248

Taking into account isoparametric numerical integration. Description of the resulting discrete problem

p. 252

Abstract error estimate

p. 255

Sufficient conditions for uniform V[subscript h]-ellipticity

p. 257

Interpolation error and consistency error estimates

p. 260

Estimate of the error [double vertical line]u - u[subscript h double vertical line subscript 1,[Omega]h]

p. 266

Exercises

p. 270

Bibliography and comments

p. 272

Additional bibliography and comments

p. 276

Problems on unbounded domains

p. 276

The Stokes problem

p. 280

Eigenvalue problems

p. 283

Application of the finite element method to some nonlinear problems

p. 287

Introduction

p. 287

The obstacle problem

p. 289

Variational formulation of the obstacle problem

p. 289

An abstract error estimate for variational inequalities

p. 291

Finite element approximation with triangles of type (1). Estimate of the error [double vertical line]u - u[subscript h double vertical line subscript 1,[Omega]

p. 294

Exercises

p. 297

The minimal surface problem

p. 301

A formulation of the minimal surface problem

p. 301

Finite element approximation with triangles of type (1). Estimate of the error [double vertical line]u - u[subscript h double vertical line subscript 1,[Omega]h]

p. 302

Exercises

p. 310

Nonlinear problems of monotone type

p. 312

A minimization problem over the space W[superscript 1,p subscript 0]([Omega]), 2 [less than or equal] p, and its finite element approximation with n-simplices of type (1)

p. 312

Sufficient condition for lim[subscript h[right arrow]0 double vertical line]u u[subscript h double vertical line subscript 1,p,[Omega] = 0

p. 317

The equivalent problem Au = f. Two properties of the operator A

p. 318

Strongly monotone operators. Abstract error estimate

p. 321

Estimate of the error [double vertical line]u - u[subscript h double vertical line subscript 1,p,[Omega]

p. 324

Exercises

p. 324

Bibliography and comments

p. 325

Additional bibliography and comments

p. 330

Other nonlinear problems

p. 330

The Navier-Stokes problem

p. 331

Finite element methods for the plate problem

p. 333

Introduction

p. 333

Conforming methods

p. 334

Conforming methods for fourth-order problems

p. 334

Almost-affine families of finite elements

p. 335

A "polynomial" finite element of class l[superscript 1]: The Argyris triangle

p. 336

A composite finite element of class l[superscript 1]: The Hsieh-Clough-Tocher triangle

p. 340

A singular finite element of class l[superscript 1]: The singular Zienkiewicz triangle

p. 347

Estimate of the error [double vertical line]u - u[subscript h double vertical line subscript 2,[Omega]

p. 352

Sufficient conditions for lim[subscript h[right arrow]0 double vertical line]u u[subscript h double vertical line subscript 2,[Omega] = 0

p. 354

Conclusions

p. 354

Exercises

p. 356

Nonconforming methods

p. 362

Nonconforming methods for the plate problem

p. 362

An example of a nonconforming finite element: Adini's rectangle

p. 364

Consistency error estimate. Estimate of the error ([Sigma subscript K[set membership]t subscript h]

p. 367

Further results

p. 373

Exercises

p. 374

Bibliography and comments

p. 376

A mixed finite element method

p. 381

Introduction

p. 381

A mixed finite element method for the biharmonic problem

p. 383

Another variational formuiation of the biharmonic problem

p. 383

The corresponding discrete problem. Abstract error estimate

p. 386

Estimate of the error (

p. 390

Concluding remarks

p. 391

Exercise

p. 392

Solution of the discrete problem by duality techniques

p. 395

Replacement of the constrained minimization problem by a saddlepoint problem

p. 395

Use of Uzawa's method. Reduction to a sequence of discrete Dirichlet problems for the operator - [Delta]

p. 399

Convergence of Uzawa's method

p. 402

Concluding remarks

p. 403

Exercises

p. 404

Bibliography and comments

p. 406

Additional bibliography and comments

p. 407

Primal, dual and primal-dual formulations

p. 407

Displacement and equilibrium methods

p. 412

Mixed methods

p. 414

Hybrid methods

p. 417

An attempt of general classification of finite element methods

p. 421

Finite element methods for shells

p. 425

Introduction

p. 425

The shell problem

p. 426

Geometrical preliminaries. Koiter's model

p. 426

Existence of a solution. Proof for the arch problem

p. 431

Exercises

p. 437

Conforming methods

p. 439

The discrete problem. Approximation of the geometry. Approximation of the displacement

p. 439

Finite element methods conforming for the displacements

p. 440

Consistency error estimates

p. 443

Abstract error estimate

p. 447

Estimate of the error ([Sigma superscript 2 subscript [alpha] = 1] [double vertical line]u[subscript [alpha] - u[subscript [alpha]h double vertical line superscript 2 subscript 1,[Omega] + [double vertical line]u[subscript 3] - u[subscript 3h double vertical line superscript 2 subscript 2,[Omega])[superscript 1/2]

p. 448

Finite element methods conforming for the geometry

p. 450

Conforming finite element methods for shells

p. 450

A nonconforming method for the arch problem

p. 451

The circular arch problem

p. 451

A natural finite element approximation

p. 452

Finite element methods conforming for the geometry

p. 453

A finite element method which is not conforming for the geometry. Definition of the discrete problem

p. 453

Consistency error estimates

p. 461

Estimate of the error (

p. 465

Exercise

p. 466

Bibliography and comments

p. 466

Epilogue: Some "real-life" finite element model examples

p. 469

Bibliography

p. 481

Glossary of symbols

p. 512

Index

p. 521

Table of Contents provided by Blackwell's Book Services and R.R. Bowker. Used with permission.