边界积分-微分方程方法的数学基础（英文版）

《边界积分-微分方程方法的数学基础（英文版）》主要讨论边界积分-微分方程的数学基础理论，可供计算数学与机械工程相关领域的研究人员和研究生参考使用。

《边界积分-微分方程方法的数学基础（英文版）》主要讨论边界积分-微分方程的数学基础理论，主要聚焦于把传统的边界积分方程中的超奇异积分转化为带弱奇性的边界积分-微分方程。《边界积分-微分方程方法的数学基础（英文版）》简要介绍了分布理论，而边界积分方程方法基于线性偏微分方程的基本解，所以对微分方程的基本解做了较为详细的介绍。在余下的章节里，依次讨论了拉普拉斯（Laplace）方程、亥姆霍兹（Helmholtz）方程、纳维（Navier）方程组、斯托克斯（Stokes）方程等的边界积分-微分方程方法和理论；还讨论了某系非线性方程，如：热辐射、变分不等式和斯捷克洛夫（Steklov）特征值问题的边界积分-微分方程理论。最后，讨论了有限元和边界元的对称耦合问题。

韩厚德，清华大学教授，长期从事计算数学研究工作。在有限元方法、无限元方法、边界元方法以及无界区域上偏微分方程的数值解等领域取得了一系列的重要研究成果。曾获得国家科学大会奖（1978），国家二等奖（1988）和一等奖（1995），北京市科技进步二等奖（2002），Hermker奖（2008），国家自然科学二等奖（2008）等多项奖励。

殷东生，清华大学副教授，主要研究方向为高频波、无界域上的偏微分方程和分数阶微分方程。

Chapter 1  Distributions  1
1.1  Space of Test Functions  2
1.2  Definition of Distributions and Their Operations  3
1.3  Direct Products and Convolution of Distributions  8
1.4  Tempered Distributions and Fourier Transform  11
References  15
Chapter 2  Fundamental Solutions of Linear Differential Operators  16
2.1  Definition of Fundamental Solution  16
2.2  Elliptic Operators  19
2.2.1  Laplace Operator  19
2.2.2  Helmholtz Operator  20
2.2.3  Biharmonic Operator  24
2.3  Transient Operator  25
2.3.1  Heat Conduction Operator  25
2.3.2  Schr?dinger Operator  26
2.3.3  Wave Operator  27
2.4  Matrix Operator  28
2.4.1  Steady-State Navier Operator  29
2.4.2  Harmonic Navier Operator  33
2.4.3  Steady-State Stokes Operator  37
2.4.4  Steady-State Oseen Operator  40
References  43
Chapter 3  Boundary Value Problems of the Laplace Equation  44
3.1  Function Spaces  44
3.1.1  Continuous and Continuously Differential Function Spaces  44
3.1.2  H?lder Spaces  45
3.1.3  The Spaces   46
3.1.4  Sobolev Spaces  47
3.2  The Dirichlet and Neumann Problems of the Laplace Equation  49
3.2.1  Classical Solutions  50
3.2.2  Generalized Solutions and Variational Problems  52
3.3  Single Layer and Double Layer Potentials  54
3.3.1  Weakly Singular Integral Operators on  55
3.3.2  Double Layer Potentials  56
3.3.3  Single Layer Potentials  62
3.3.4  The Derivatives of Single Layer Potentials  64
3.3.5  The Derivatives of Double Layer Potentials  67
3.3.6  The Single and Double Layer Potentials in Sobolev Spaces  70
3.4  Boundary Reduction  73
3.4.1  Boundary Integral (Integro-Differential) Equations of the First Kind  73
3.4.2  Solvability of First Kind Integral Equation with n=2 and the Degenerate 
Scale  79
3.4.3  Boundary Integral Equations of the Second Kind  84
References  93
Chapter 4  Boundary Value Problems of Modified Helmholtz Equation  95
4.1  The Dirichlet and Neumann Boundary Problems of Modified Helmholtz Equation  95
4.2  Single and Double Layer Potentials of Modified Helmholtz
Operator for the Continuous Densities  98
4.3  Single Layer Potential  and Double Layer Potential  
in Soblov Spaces  106
4.4  Boundary Reduction for the Boundary Value Problems of Modified
Helmholtz Equation  115
4.4.1  Boundary Integral Equation and Integro-Differential Equation of
the First Kind  115
4.4.2  Boundary Integral Equations of the Second Kind  118
References  125
Chapter 5  Boundary Value Problems of Helmholtz Equation  127
5.1  Interior and Exterior Boundary Value Problems of Helmholtz Equation  128
5.2  Single and Double Layers Potentials of Helmholtz Equation  133
5.2.1  Single Layer Potential   136
5.2.2  The Double Layer Potential  142
5.3  Boundary Reduction for the Principal Boundary Value Problems
of Helmholtz Equation  149
5.3.1  Boundary Integral Equation of the First Kind  151
5.3.2  Boundary Integro-Differential Equations of the First Kind  156
5.3.3  Boundary Integral Equations of the Second Kind  162
5.3.4  Modified Integral and Integro-Differential Equations  176
5.4  The Boundary Integro-Differential Equation Method for Interior
Dirichlet and Neumann Eigenvalue Problems of Laplace Operator  179
5.4.1  Interior Dirichlet Eigenvalue Problems of Laplace Operator  179
5.4.2  Interior Neuamann Eigenvalue Problem of Laplace Operator  182
References  185
Chapter 6  Boundary Value Problems of the Navier Equations  186
6.1  Some Basic Boundary Value Problems  186
6.2  Single and Double Layer Potentials of the Navier System  191
6.2.1  Single Layer Potential   191
6.2.2  Double Layer Potential  192
6.2.3  The Derivatives of the Single Layer Potential   195
6.2.4  The Derivatives of the Double Layer Potential   197
6.2.5  The Layer Potentials  and  in Sobolev Spaces  202
6.3  Boundary Reduction for the Boundary Value Problems of the Navier System  204
6.3.1  First Kind Integral (Differential-integro-differential) Equations of
the Boundary Value Problems of the Navier System  205
6.3.2  Solvability of the First Kind Integral Equations with n = 2 and
the Degenerate Scales  212
6.3.3  The Second Kind Integral Equations of the Boundary Value
Problems of the Navier System  218
References  225
Chapter 7  Boundary Value Problems of the Stokes Equations  227
7.1  Principal Boundary Value Problems of Stokes equations  227
7.2  Single Layer Potential and Double Layer Potential of Stokes Operator  234
7.3  Boudary Reduction of the Boundary Value Problems of Stokes Equations  243
References  247
Chapter 8  Some Nonlinear Problems  248
8.1  Heat Radiation Problems  248
8.1.1  Boundary Condition of Nonlinear Boundary Problem (8.1.1)  249
8.1.2  Equivalent Formula of Problem (8.1.1)  250
8.1.3  Equivalent Saddle-point Problem  255
8.1.4  The Numerical Solutions of Nonlinear Boundary   
Variational Problem (8.1.17)  257
8.2  Variational Inequality (I)-Laplace Equation with Unilateral
 Boundary Conditions  259
8.2.1  Equivalent Boundary Variational Inequality of Problem (8.2.2)  260
8.2.2  Abstract Error Estimate of the Numerical Solution of
Boundary Variational Inequality (8.2.9)  262
8.3  Variational Inequality (II)-Signorini Problems in Linear Elasticity  264
8.3.1  Signorini Problems in Linear Elasticity  264
8.3.2  An Equivalent Boundary Variational Inequality of Problem (8.3.3)  265
8.4  Steklov Eigenvalue Problems  268
8.4.1  The Boundary Reduction of Steklov Eigenvalue Problem  270
8.4.2  The Numerical Solutions of Steklov Eigenvalue Problem Based
on the Variational Form (8.4.13)  272
8.4.3  The Error Estimate of Numerical Solution of Steklov
Eigenvalue Problem  273
References  282
Chapter 9   Coercive and Symmetrical Coupling Methods of Finite
 Element Method and Boundary Element Method  285
9.1  Exterior Dirichelet Problem of Poisson’s Equation (I)   286
9.1.1  The Symmetric and Coercive Coupling Formula of Problem (9.1.1)  286
9.1.2  The Numerical Solutions of Problem (9.1.1) Based on the
Symmetric and Coercive Coupling Formula  291
9.2  Exterior Dirichlet Problem of Poisson Equation (II)  292
9.3  An Exterior Displacement Problem of Nonhomogeneous Navier System  298
9.3.1  The Coercive and Symmetrical Variational Formulation
of Problem (9.3.1) on Bounded Domain  298
9.3.2  The Discrete Approximation of Problem (9.3.19) and (9.3.20)  303
References  304

This book is focused on the mathematical foundation of the boundary integro-differential equation method. It is well known that the boundary integral equation method (or boundary element method) has become one effective numerical computational method for solving the boundary value problems of partial differential equations, that have been formulated as boundary integral equations including the hypersingular boundary integral equations.~The hypersingular boundary integral operators are derived from the derivative of double layer potential corresponding to the given problem. From the view of science and engineering computing, the appearance of the hypersingular boundary integral operators has caused new difficulties in the boundary integral equation method. One way to resolve the difficulties is to find the computing method for the hypersingular boundary integral operators. In this book, we prefer to resolve the difficulties from a different perspective. The hypersingular boundary integral operators are regularized as boundary integro-differential operators with only weak singular boundary integral operators. It means that each of the hypersingular boundary integral operators is equivalent to a corresponding boundary integro-differential operator with only a weak singular boundary integral operator. The hypersingular boundary integral operators no longer appear; they are replaced by the corresponding integro-differential operators. Therefore the difficulties in computing hypersingular integral operators have completely disappeared. It is the  motivation for  the title of this book.
The book also pays attention to the boundary integral equations of the first kind and the boundary integro-differential equations of the first kind. They occur in the acoustic scattering theory, as pointed out by Colton and Kress in their book (2013) “Traditionally, the use of integral equations of the first kind for studying boundary-value problems in acoustic scattering theory has been neglected due to the lack of a Riesz-Fredholm theory for equations of the first kind and the fact that integral equations of the first kind are improperly posed.~” But in Chapter 5 of this book boundary integral equations of the first kind and boundary integro-differential equations of the first kind are used to study the boundary value problems of the Helmholtz equation, because the Fredholm alternative theorems are established for the corresponding boundary integral equations of the first kind and boundary integro-differential equations of the first kind.
We also discuss in the last two chapters, the application of the boundary integro-differential equation method to nonlinear problems and the coercive and symmetrical coupling method of finite element method and boundary element method based on the boundary integro-differential operators.
This book contains nine Chapters, as listed below.
Chapter 1: Distributions
Chapter 2: Fundamental Solutions of Linear Differential Operators
Chapter 3: Boundary Value Problems of the Laplace Equation
Chapter 4: Boundary Value Problems of Modified Helmholtz Equation
Chapter 5: Boundary Value Problems of Helmholtz Equation
Chapter 6: Boundary Value Problems of the Navier Equations
Chapter 7: Boundary Value Problems of the Stokes Equations
Chapter 8: Some Nonlinear Problems
Chapter 9: Coercive and Symmetrical Coupling Methods of Finite Element Method and Boundary Element Method
Due to the limited knowledge of the authors, errors are inevitable. We would be most grateful to learn of any errors in the book and any suggestions for the revision of a future printing.
We are very grateful for the support and encouragement from our colleagues and friends during the preparing this book. Prof. Hermann Brunner carefully read the whole book and gave helpful suggestions for revision. This book has benefited from the works of many other researchers, including our co-authors: Weijun Tang, Zhi Guan, Bin He, Chongqing Yu, Jeng-Tzong Chen, Ying-Te Lee, Wenjun Ying, etc.

Houde Han, Dongsheng Yin