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E-raamat: Numerical Methods for Stochastic Partial Differential Equations with White Noise

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  • Formaat: PDF+DRM
  • Sari: Applied Mathematical Sciences 196
  • Ilmumisaeg: 01-Sep-2017
  • Kirjastus: Springer International Publishing AG
  • Keel: eng
  • ISBN-13: 9783319575117
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Numerical Methods for Stochastic Partial Differential Equations with White NoiseSuurem pilt
  • Formaat: PDF+DRM
  • Sari: Applied Mathematical Sciences 196
  • Ilmumisaeg: 01-Sep-2017
  • Kirjastus: Springer International Publishing AG
  • Keel: eng
  • ISBN-13: 9783319575117
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This book covers numerical methods for stochastic partial differential equations with white noise using the framework of Wong-Zakai approximation. The book begins with some motivational and background material in the introductory chapters and is divided into three parts. Part I covers numerical stochastic ordinary differential equations. Here the authors start with numerical methods for SDEs with delay using the Wong-Zakai approximation and finite difference in time. Part II covers temporal white noise. Here the authors consider SPDEs as PDEs driven by white noise, where discretization of white noise (Brownian motion) leads to PDEs with smooth noise, which can then be treated by numerical methods for PDEs. In this part, recursive algorithms based on Wiener chaos expansion and stochastic collocation methods are presented for linear stochastic advection-diffusion-reaction equations. In addition, stochastic Euler equations are exploited as an application of stochastic collocation methods, where a numerical comparison with other integration methods in random space is made. Part III covers spatial white noise. Here the authors discuss numerical methods for nonlinear elliptic equations as well as other equations with additive noise. Numerical methods for SPDEs with multiplicative noise are also discussed using the Wiener chaos expansion method. In addition, some SPDEs driven by non-Gaussian white noise are discussed and some model reduction methods (based on Wick-Malliavin calculus) are presented for generalized polynomial chaos expansion methods. Powerful techniques are provided for solving stochastic partial differential equations.

This book can be considered as self-contained. Necessary background knowledge is presented in the appendices. Basic knowledge of probability theory and stochastic calculus is presented in Appendix A. In Appendix B some semi-analytical methods for SPDEs are presented. In Appendix C an introduction to Gauss quadrature is provided.In Appendix D, all the conclusions which are needed for proofs are presented, and in Appendix E a method to compute the convergence rate empirically is included.





In addition, the authors provide a thorough review of the topics, both theoretical and computational exercises in the book with practical discussion of the effectiveness of the methods. Supporting Matlab files are made available to help illustrate some of the concepts further. Bibliographic notes are included at the end of each chapter. This book serves as a reference for graduate students and researchers in the mathematical sciences who would like to understand state-of-the-art numerical methods for stochastic partial differential equations with white noise.

Arvustused

Zhang and Karniadakis book may be used as a textbook, but it may also be considered as a reference for the state of the art concerning the numerical solution of stochastic differential equations involving white noise/Wiener processes/ Brownian motion. Bibliographic notes address the state of the art in the field. Appendices give the necessary background in probability, stochastic calculus, semi-analytical approximation methods for stochastics differential equation, Gauss quadrature . (José Eduardo Souze de Cursi, Mathematical Reviews, September, 2018)







It is an interesting book on numerical methods for stochastic partial differential equations with white noise through the framework of Wong-Zakai approximation. ... . It is to be noted that the authors provide a thorough review of topics both theoretical and computational exercises to justify the effectiveness of the developed methods. Further, the MATLAB files are made available to the researchers and readers to understand the state of art of numerical methods for stochastic partial differential equations. (Prabhat Kumar Mahanti, zbMATH 1380.65021, 2018)

Preface v
1 Prologue
1(10)
1.1 Why random and Brownian motion (white noise)?
1(3)
1.2 Modeling with SPDEs
4(3)
1.3 Specific topics of this book
7(4)
2 Brownian motion and stochastic calculus
11(42)
2.1 Gaussian processes and their representations
11(6)
2.2 Brownian motion and white noise
17(8)
2.2.1 Some properties of Brownian motion
18(3)
2.2.2 Approximation of Brownian motion
21(4)
2.3 Brownian motion and stochastic calculus
25(4)
2.4 Stochastic chain rule: Ito formula
29(2)
2.5 Integration methods in random space
31(15)
2.5.1 Monte Carlo method and its variants
31(3)
2.5.2 Quasi-Monte Carlo methods
34(1)
2.5.3 Wiener chaos expansion method
35(2)
2.5.4 Stochastic collocation method
37(3)
2.5.5 Application to SODEs
40(6)
2.6 Bibliographic notes
46(4)
2.7 Suggested practice
50(3)
3 Numerical methods for stochastic differential equations
53(50)
3.1 Basic aspects of SODEs
53(7)
3.1.1 Existence and uniqueness of strong solutions
54(2)
3.1.2 Solution methods
56(4)
3.2 Numerical methods for SODEs
60(9)
3.2.1 Derivation of numerical methods based on numerical integration
60(2)
3.2.2 Strong convergence
62(2)
3.2.3 Weak convergence
64(2)
3.2.4 Linear stability
66(3)
3.2.5 Summary of numerical SODEs
69(1)
3.3 Basic aspects of SPDEs
69(11)
3.3.1 Functional spaces
72(1)
3.3.2 Solutions in different senses
73(3)
3.3.3 Solutions to SPDEs in explicit form
76(1)
3.3.4 Linear stochastic advection-diffusion-reaction equations
77(1)
3.3.5 Existence and uniqueness
77(1)
3.3.6 Conversion between Ito and Stratonovich formulation
78(2)
3.4 Numerical methods for SPDEs
80(14)
3.4.1 Direct semi-discretization methods for parabolic SPDEs
82(3)
3.4.2 Wong-Zakai approximation for parabolic SPDEs
85(1)
3.4.3 Preprocessing methods for parabolic SPDEs
86(2)
3.4.4 What could go wrong? Examples of stochastic Burgers and Navier-Stokes equations
88(2)
3.4.5 Stability and convergence of existing numerical methods
90(3)
3.4.6 Summary of numerical SPDEs
93(1)
3.5 Summary and bibliographic notes
94(2)
3.6 Suggested practice
96(7)
Part I Numerical Stochastic Ordinary Differential Equations
4 Numerical schemes for SDEs with time delay using the Wong-Zakai approximation
103(32)
4.1 Wong-Zakai approximation for SODEs
104(2)
4.1.1 Wong-Zakai approximation for SDDEs
105(1)
4.2 Derivation of numerical schemes
106(13)
4.2.1 A predictor-corrector scheme
107(4)
4.2.2 The midpoint scheme
111(2)
4.2.3 A Milstein-like scheme
113(6)
4.3 Linear stability of some schemes
119(4)
4.4 Numerical results
123(6)
4.5 Summary and bibliographic notes
129(3)
4.6 Suggested practice
132(3)
5 Balanced numerical schemes for SDEs with non-Lipschitz coefficients
135(30)
5.1 A motivating example
135(2)
5.2 Fundamental theorem
137(8)
5.2.1 On application of Theorem 5.2.3
140(1)
5.2.2 Proof of the fundamental theorem
141(4)
5.3 A balanced Euler scheme
145(8)
5.4 Numerical examples
153(5)
5.4.1 Some numerical schemes
153(2)
5.4.2 Numerical results
155(3)
5.5 Summary and bibliographic notes
158(1)
5.6 Suggested practice
159(6)
Part II Temporal White Noise
6 Wiener chaos methods for linear stochastic advection-diffusion-reaction equations
165(26)
6.1 Description of methods
165(8)
6.1.1 Multistage WCE method
166(4)
6.1.2 Algorithm for computing moments
170(3)
6.2 Examples in one dimension
173(4)
6.2.1 Numerical results for one-dimensional advection-diffusion-reaction equations
175(2)
6.3 Comparison of the WCE algorithm and Monte Carlo type algorithms
177(4)
6.4 A two-dimensional passive scalar equation
181(5)
6.4.1 A Monte Carlo method based on the method of characteristics
184(1)
6.4.2 Comparison between recursive WCE and Monte Carlo methods
185(1)
6.5 Summary and bibliographic notes
186(2)
6.6 Suggested practice
188(3)
7 Stochastic collocation methods for differential equations with white noise
191(24)
7.1 Introduction
191(2)
7.2 Isotropic sparse grid for weak integration of SDE
193(9)
7.2.1 Probabilistic interpretation of SCM
193(1)
7.2.2 Illustrative examples
194(8)
7.3 Recursive collocation algorithm for linear SPDEs
202(4)
7.4 Numerical results
206(6)
7.5 Summary and bibliographic notes
212(2)
7.6 Suggested practice
214(1)
8 Comparison between Wiener chaos methods and stochastic collocation methods
215(32)
8.1 Introduction
215(1)
8.2 Review of Wiener chaos and stochastic collocation
216(4)
8.2.1 Wiener chaos expansion (WCE)
216(1)
8.2.2 Stochastic collocation method (SCM)
217(3)
8.3 Error estimates
220(16)
8.3.1 Error estimates for WCE
221(6)
8.3.2 Error estimate for SCM
227(9)
8.4 Numerical results
236(8)
8.5 Summary and bibliographic notes
244(1)
8.6 Suggested practice
245(2)
9 Application of collocation method to stochastic conservation laws
247(20)
9.1 Introduction
247(2)
9.2 Theoretical background
249(3)
9.2.1 Stochastic Euler equations
250(2)
9.3 Verification of the Stratonovich- and Ito-Euler equations
252(3)
9.3.1 A splitting method for stochastic Euler equations
252(1)
9.3.2 Stratonovich-Euler equations versus first-order perturbation analysis
253(1)
9.3.3 Stratonovich-Euler equations versus Ito-Euler equations
254(1)
9.4 Applying the stochastic collocation method
255(3)
9.5 Summary and bibliographic notes
258(3)
9.6 Suggested practice
261(6)
Part III Spatial White Noise
10 Semilinear elliptic equations with additive noise
267(26)
10.1 Introduction
267(2)
10.2 Assumptions and schemes
269(2)
10.3 Error estimates for strong and weak convergence order
271(11)
10.3.1 Examples of other PDEs
272(3)
10.3.2 Proofs of the strong convergence order
275(3)
10.3.3 Weak convergence order
278(4)
10.4 Error estimates for finite element approximation
282(6)
10.5 Numerical results
288(1)
10.6 Summary and bibliographic notes
289(2)
10.7 Suggested practice
291(2)
11 Multiplicative white noise: The Wick-Malliavin approximation
293(38)
11.1 Introduction
293(2)
11.2 Approximation using the Wick-Malliavin expansion
295(2)
11.3 Lognormal coefficient
297(3)
11.3.1 One-dimensional example
299(1)
11.4 White noise as coefficient
300(11)
11.4.1 Error Estimates
303(7)
11.4.2 Numerical results
310(1)
11.5 Application of Wick-Malliavin approximation to nonlinear SPDEs
311(2)
11.6 Wick-Malliavin approximation: extensions for non-Gaussian white noise
313(12)
11.6.1 Numerical results
318(3)
11.6.2 Malliavin derivatives for Poisson noises
321(4)
11.7 Summary and bibliographic notes
325(4)
11.8 Suggested practice
329(2)
12 Epilogue
331(8)
12.1 A review of this work
331(3)
12.2 Some open problems
334(5)
Appendices
A Basics of probability
339(6)
A.1 Probability space
339(1)
A.1.1 Random variable
339(1)
A.2 Conditional expectation
340(1)
A.2.1 Properties of conditional expectation
341(1)
A.2.2 Filtration and Martingales
342(1)
A.3 Continuous time stochastic process
343(2)
B Semi-analytical methods for SPDEs
345(2)
C Gauss quadrature
347(6)
C.1 Gauss quadrature
347(3)
C.2 Gauss-Hermite quadrature
350(3)
D Some useful inequalities and lemmas
353(4)
E Computation of convergence rate
357(2)
References 359(32)
Index 391
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