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Unified Approach to Boundary Value Problems [Minkštas viršelis]

  • Formatas: Paperback / softback, 351 pages, aukštis x plotis x storis: 229x152x15 mm, weight: 565 g, Illustrations
  • Serija: CBMS-NSF Regional Conference Series in Applied Mathematics No. 78
  • Išleidimo metai: 30-Aug-2008
  • Leidėjas: Society for Industrial & Applied Mathematics,U.S.
  • ISBN-10: 0898716519
  • ISBN-13: 9780898716511
Kitos knygos pagal šią temą:
Unified Approach to Boundary Value ProblemsDidesnis paveikslėlis
  • Formatas: Paperback / softback, 351 pages, aukštis x plotis x storis: 229x152x15 mm, weight: 565 g, Illustrations
  • Serija: CBMS-NSF Regional Conference Series in Applied Mathematics No. 78
  • Išleidimo metai: 30-Aug-2008
  • Leidėjas: Society for Industrial & Applied Mathematics,U.S.
  • ISBN-10: 0898716519
  • ISBN-13: 9780898716511
Kitos knygos pagal šią temą:
Pastovi nuoroda: https://www.kriso.lt/db/9780898716511.html
Raktažodžiai:
Presents a new approach to analyzing initial-boundary value problems for integrable partial differential equations (PDEs) in two dimensions, a method that the author first introduced in 1997 and which is based on ideas of the inverse scattering transform. This method is unique in also yielding novel integral representations for the explicit solution of linear boundary value problems, which include such classical problems as the heat equation on a finite interval and the Helmholtz equation in the interior of an equilateral triangle.

The authors thorough introduction allows the interested reader to quickly assimilate the essential results of the book, avoiding many computational details. Several new developments are addressed in the book, including a new transform method for linear evolution equations on the half-line and on the finite interval; analytical inversion of certain integrals such as the attenuated radon transform and the Dirichlet-to-Neumann map for a moving boundary; analytical and numerical methods for elliptic PDEs in a convex polygon; and integrable nonlinear PDEs.

An epilogue provides a list of problems on which the authors new approach has been used, offers open problems, and gives a glimpse into how the method might be applied to problems in three dimensions.

Several new developments are addressed in the book, including:

A new transform method for linear evolution equations on the half-line and on the finite interval. Analytical inversion of certain integrals such as the attenuated Radon transform and the Dirichlet-to-Neumann map for a moving boundary. Integral representations for linear boundary value problems. Analytical and numerical methods for elliptic PDEs in a convex polygon. Integrable nonlinear PDEs.
Preface xiii
Introduction 1(1)
Historical Remarks 1(2)
A Generalization of the Classical Transforms for Linear Evolution Equations
3(10)
Inversion of Intergrals
13(3)
Novel Integral Representation for Linear PDEs
16(3)
Green's Identities, Images, Transforms, and the Wiener-Hopf Technique: A Unification
19(7)
Nonlinearization of the Formulation in the Spectral Plane
26(9)
A new Transform Method for Linear Evolution Equations
35(2)
I Evolution Equations on the Half-Line
37(50)
The Classical Representations: Return to the Real Line
53(16)
Forced Problems
55(1)
Green's Function Type Representations
55(2)
The Generalized Dirichlet to Neumann Correspondence
57(2)
Rigorous Considerations
59(4)
Evolution Equations on the Finite Interval
63(6)
The Classical Representations: Return to the Real Line
69(9)
Forced Problems
73(1)
Green's Function Type Representations
73(4)
Asymptotics and a Novel Numerical Technique
77(1)
The Heat Equation on the Half-Line
78(9)
The Equation qt + qxxx = O on the Half-Line
80(1)
The Equation qt - qxxx = O on the Half-Line
81(4)
Analytical Inversion of Integrals
85(2)
II From PDEs to Classical Transforms
87(38)
From PDEs to Classical Transfroms
57(34)
Riemann-Hilbert and d-Bar Problems
91(6)
Plemelj Formula
91(3)
The d-Bar Problem
94(3)
The Fourier Transform and Its Variations
97(6)
The Inversion of the Attenuated Radon Transform and Medical Imaging
103(10)
Computerized Tomography
103(1)
PET and SPECT
103(2)
The Mathematics of PET and SPECT
105(5)
Numerical Implementation
110(3)
The Dirichlet to Neumann Map for a Moving Boundary
113(12)
The Solution of the Global Relation
119(3)
Examples
122(3)
III Novel Integral Representations for Linear Boundary Value Problems
125(34)
Divergence Formulation, the Globla Relations, and Lax Pairs
129(8)
Rederivation of the Integral Representation on the Half-Line and the Finite Interval
137(4)
The Basic Elliptic PDEs in a Polygonal Domain
141(18)
The Laplace Equation in a Convex Polygon
141(7)
The Modified Hlmholtz Equation in a Convex Polygon
148(3)
The Helmoholtz Equation in the Quarter Plane
151(4)
From the Physical to the Spectral Plane
155(4)
IV Novel Analytical and Numerical Methods for Elliptic PDEs in a Convex Polygon
159(54)
The New Transform Method for Elliptic PDEs in Simple Polygonal Domains
163(26)
The Laplace Eqration in the Quarter Plane
164(4)
The Laplace Equation in a Semi-Infinite Strip
168(3)
The Modified Helmholtz Equation in a Semi-Infinite Strip
171(5)
The Helmholtz Equation in the Quarter Plane
176(2)
The Modified Helmholtz Equation in an Equilateral Triangle
178(6)
The Dirichlet to Neumann Correspondence
184(5)
Formulation of Riemann-Hilbert Problems
189(6)
The Laplace Equation in the Quarter Plane
189(1)
The Laplace Equation in a Semi-Infinite Strip
190(2)
The Modified Helmholtz Equation in a Semi-Infinite Strip
192(3)
A Collocation Method in the Fourier Plane
195(18)
The Laplace Equation
195(8)
The Modified Helmholtz Equation
203(3)
Further Developments and Numerical Computations
206(7)
V Integrable Nonlinear PDEs
213(102)
From Linear to Integrable Nonlinear PDEs
217(8)
A Lax Pair Formulation
217(1)
A Scalar RH Problem
218(2)
A Matrix RH Problem
220(1)
The Dressing Method
220(5)
Nonlinear Integrable PDEs on the Half-Line
225(46)
The NLS Equation
226(29)
The Modified KdV, KdV, and sG Equations
255(16)
Linearizable Boundary Conditions
271(12)
Additional Linearizable Boundary Value Problems
281(2)
The Generalized Dirichlet to Neumann Map
283(18)
The Gel'fand-Levitan-Marchenko Representations
285(6)
The Solution of the Global Relation in Terms of the GLM Functions
291(5)
The Solution of the Global Relation in Terms of Φ(t, k)
296(5)
Asymptotics of Oscillatory Riemann-Hilbert Problems
301(14)
The Large-t Limit of the Nonlinear Schrodinger Equation on the Half-Line
301(7)
Asymptotics in Transient Stimulated Raman Scattering
308(7)
Epilogue 315(6)
Bibliography 321(14)
Index 335
Athanassios S. Fokas is Professor of Nonlinear Mathematical Science in the Department of Applied Mathematics and Theoretical Physics at the University of Cambridge. In 2000 he was awarded the Naylor Prize for his work on which this book is based. In 2006 he received the Excellence Prize of the Bodossaki Foundation.