Holder-Sobolev Regularity of the Solution to the Stochastic Wave Equation in Dimension Three
Holder-Sobolev Regularity of the Solution to the Stochastic Wave Equation in Dimension Three

Author: Robert C. Dalang

Publisher: American Mathematical Soc.

Published: 2009-04-10

Total Pages: 83

ISBN-13: 0821842889

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The authors study the sample path regularity of the solution of a stochastic wave equation in spatial dimension $d=3$. The driving noise is white in time and with a spatially homogeneous covariance defined as a product of a Riesz kernel and a smooth function. The authors prove that at any fixed time, a.s., the sample paths in the spatial variable belong to certain fractional Sobolev spaces. In addition, for any fixed $x\in\mathbb{R}^3$, the sample paths in time are Holder continuous functions. Further, the authors obtain joint Holder continuity in the time and space variables. Their results rely on a detailed analysis of properties of the stochastic integral used in the rigourous formulation of the s.p.d.e., as introduced by Dalang and Mueller (2003). Sharp results on one- and two-dimensional space and time increments of generalized Riesz potentials are a crucial ingredient in the analysis of the problem. For spatial covariances given by Riesz kernels, the authors show that the Holder exponents that they obtain are optimal.

A Minicourse on Stochastic Partial Differential Equations
A Minicourse on Stochastic Partial Differential Equations

Author: Robert C. Dalang

Publisher: Springer Science & Business Media

Published: 2009

Total Pages: 230

ISBN-13: 3540859934

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This title contains lectures that offer an introduction to modern topics in stochastic partial differential equations and bring together experts whose research is centered on the interface between Gaussian analysis, stochastic analysis, and stochastic PDEs.

Analysis of Variations for Self-similar Processes
Analysis of Variations for Self-similar Processes

Author: Ciprian Tudor

Publisher: Springer Science & Business Media

Published: 2013-08-13

Total Pages: 272

ISBN-13: 3319009362

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Self-similar processes are stochastic processes that are invariant in distribution under suitable time scaling, and are a subject intensively studied in the last few decades. This book presents the basic properties of these processes and focuses on the study of their variation using stochastic analysis. While self-similar processes, and especially fractional Brownian motion, have been discussed in several books, some new classes have recently emerged in the scientific literature. Some of them are extensions of fractional Brownian motion (bifractional Brownian motion, subtractional Brownian motion, Hermite processes), while others are solutions to the partial differential equations driven by fractional noises. In this monograph the author discusses the basic properties of these new classes of self-similar processes and their interrelationship. At the same time a new approach (based on stochastic calculus, especially Malliavin calculus) to studying the behavior of the variations of self-similar processes has been developed over the last decade. This work surveys these recent techniques and findings on limit theorems and Malliavin calculus.

Stochastic Partial Differential Equations With Additive Gaussian Noise - Analysis And Inference
Stochastic Partial Differential Equations With Additive Gaussian Noise - Analysis And Inference

Author: Ciprian A Tudor

Publisher: World Scientific

Published: 2022-10-11

Total Pages: 205

ISBN-13: 9811264473

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The stochastic partial differential equations (SPDEs) arise in many applications of the probability theory. This monograph will focus on two particular (and probably the most known) equations: the stochastic heat equation and the stochastic wave equation.The focus is on the relationship between the solutions to the SPDEs and the fractional Brownian motion (and related processes). An important point of the analysis is the study of the asymptotic behavior of the p-variations of the solutions to the heat or wave equations driven by space-time Gaussian noise or by a Gaussian noise with a non-trivial correlation in space.The book is addressed to public with a reasonable background in probability theory. The idea is to keep it self-contained and avoid using of complex techniques. We also chose to insist on the basic properties of the random noise and to detail the construction of the Wiener integration with respect to them. The intention is to present the proofs complete and detailed.

Malliavin Calculus
Malliavin Calculus

Author: Marta Sanz Solé

Publisher: EPFL Press

Published: 2005-01-01

Total Pages: 184

ISBN-13: 9782940222063

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Developed in the 1970s to study the existence and smoothness of density for the probability laws of random vectors, Malliavin calculus--a stochastic calculus of variation on the Wiener space--has proven fruitful in many problems in probability theory, particularly in probabilistic numerical methods in financial mathematics. This book presents applications of Malliavin calculus to the analysis of probability laws of solutions to stochastic partial differential equations driven by Gaussian noises that are white in time and coloured in space. The first five chapters introduce the calculus itself b.

Hitting Probabilities for Nonlinear Systems of Stochastic Waves
Hitting Probabilities for Nonlinear Systems of Stochastic Waves

Author: Robert C. Dalang

Publisher: American Mathematical Soc.

Published: 2015-08-21

Total Pages: 88

ISBN-13: 1470414236

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The authors consider a d-dimensional random field u={u(t,x)} that solves a non-linear system of stochastic wave equations in spatial dimensions k∈{1,2,3}, driven by a spatially homogeneous Gaussian noise that is white in time. They mainly consider the case where the spatial covariance is given by a Riesz kernel with exponent β. Using Malliavin calculus, they establish upper and lower bounds on the probabilities that the random field visits a deterministic subset of Rd, in terms, respectively, of Hausdorff measure and Newtonian capacity of this set. The dimension that appears in the Hausdorff measure is close to optimal, and shows that when d(2−β)>2(k+1), points are polar for u. Conversely, in low dimensions d, points are not polar. There is, however, an interval in which the question of polarity of points remains open.