GLOBAL WELL-POSEDNESS OF THE VISCOUS CAMASSA–HOLM EQUATION WITH GRADIENT NOISE

Helge Holden; Kenneth H. Karlsen; Peter H.C. Pang

doi:10.3934/dcds.2022163

GLOBAL WELL-POSEDNESS OF THE VISCOUS CAMASSA–HOLM EQUATION WITH GRADIENT NOISE

Helge Holden
, Kenneth H. Karlsen
, Peter H.C. Pang

Research output: Journal Publication › Article › peer-review

13 Citations (Scopus)

Abstract

We analyse a nonlinear stochastic partial differential equation that corresponds to a viscous shallow water equation (of the Camassa–Holm type) perturbed by a convective, position-dependent noise term. We establish the existence of weak solutions in H^m (m ∈ N) using Galerkin approximations and the stochastic compactness method. We derive a series of a priori estimates that combine a model-specific energy law with non-standard regularity estimates. We make systematic use of a stochastic Gronwall inequality and also stopping time techniques. The proof of convergence to a solution argues via tightness of the laws of the Galerkin solutions, and Skorokhod–Jakubowski a.s. representations of random variables in quasi-Polish spaces. The spatially dependent noise function constitutes a complication throughout the analysis, repeatedly giving rise to nonlinear terms that “balance” the martingale part of the equation against the second-order Stratonovich-to-Itô correction term. Finally, via pathwise uniqueness, we conclude that the constructed solutions are probabilistically strong. The uniqueness proof is based on a finite-dimensional Itô formula and a DiPerna–Lions type regularisation procedure, where the regularisation errors are controlled by first and second order commutators.

Original language	English
Pages (from-to)	568-618
Number of pages	51
Journal	Discrete and Continuous Dynamical Systems
Volume	43
Issue number	2
DOIs	https://doi.org/10.3934/dcds.2022163
Publication status	Published - Feb 2023
Externally published	Yes

Free Keywords

Faedo–Galerkin method
Shallow water equation
Skorokhod–Jakubowski representation
commutator estimate
compactness
convective noise
existence
stochastic perturbation
tightness
uniqueness
viscous Camassa–Holm equation

ASJC Scopus subject areas

Analysis
Discrete Mathematics and Combinatorics
Applied Mathematics

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@article{7094d0b39e90485a94ad26f737bb2f8a,

title = "GLOBAL WELL-POSEDNESS OF THE VISCOUS CAMASSA–HOLM EQUATION WITH GRADIENT NOISE",

abstract = "We analyse a nonlinear stochastic partial differential equation that corresponds to a viscous shallow water equation (of the Camassa–Holm type) perturbed by a convective, position-dependent noise term. We establish the existence of weak solutions in Hm (m ∈ N) using Galerkin approximations and the stochastic compactness method. We derive a series of a priori estimates that combine a model-specific energy law with non-standard regularity estimates. We make systematic use of a stochastic Gronwall inequality and also stopping time techniques. The proof of convergence to a solution argues via tightness of the laws of the Galerkin solutions, and Skorokhod–Jakubowski a.s. representations of random variables in quasi-Polish spaces. The spatially dependent noise function constitutes a complication throughout the analysis, repeatedly giving rise to nonlinear terms that “balance” the martingale part of the equation against the second-order Stratonovich-to-It{\^o} correction term. Finally, via pathwise uniqueness, we conclude that the constructed solutions are probabilistically strong. The uniqueness proof is based on a finite-dimensional It{\^o} formula and a DiPerna–Lions type regularisation procedure, where the regularisation errors are controlled by first and second order commutators.",

keywords = "Faedo–Galerkin method, Shallow water equation, Skorokhod–Jakubowski representation, commutator estimate, compactness, convective noise, existence, stochastic perturbation, tightness, uniqueness, viscous Camassa–Holm equation",

author = "Helge Holden and Karlsen, \{Kenneth H.\} and Pang, \{Peter H.C.\}",

year = "2023",

month = feb,

doi = "10.3934/dcds.2022163",

language = "English",

volume = "43",

pages = "568--618",

journal = "Discrete and Continuous Dynamical Systems",

issn = "1078-0947",

publisher = "American Institute of Mathematical Sciences",

number = "2",

}

TY - JOUR

T1 - GLOBAL WELL-POSEDNESS OF THE VISCOUS CAMASSA–HOLM EQUATION WITH GRADIENT NOISE

AU - Holden, Helge

AU - Karlsen, Kenneth H.

AU - Pang, Peter H.C.

PY - 2023/2

Y1 - 2023/2

N2 - We analyse a nonlinear stochastic partial differential equation that corresponds to a viscous shallow water equation (of the Camassa–Holm type) perturbed by a convective, position-dependent noise term. We establish the existence of weak solutions in Hm (m ∈ N) using Galerkin approximations and the stochastic compactness method. We derive a series of a priori estimates that combine a model-specific energy law with non-standard regularity estimates. We make systematic use of a stochastic Gronwall inequality and also stopping time techniques. The proof of convergence to a solution argues via tightness of the laws of the Galerkin solutions, and Skorokhod–Jakubowski a.s. representations of random variables in quasi-Polish spaces. The spatially dependent noise function constitutes a complication throughout the analysis, repeatedly giving rise to nonlinear terms that “balance” the martingale part of the equation against the second-order Stratonovich-to-Itô correction term. Finally, via pathwise uniqueness, we conclude that the constructed solutions are probabilistically strong. The uniqueness proof is based on a finite-dimensional Itô formula and a DiPerna–Lions type regularisation procedure, where the regularisation errors are controlled by first and second order commutators.

AB - We analyse a nonlinear stochastic partial differential equation that corresponds to a viscous shallow water equation (of the Camassa–Holm type) perturbed by a convective, position-dependent noise term. We establish the existence of weak solutions in Hm (m ∈ N) using Galerkin approximations and the stochastic compactness method. We derive a series of a priori estimates that combine a model-specific energy law with non-standard regularity estimates. We make systematic use of a stochastic Gronwall inequality and also stopping time techniques. The proof of convergence to a solution argues via tightness of the laws of the Galerkin solutions, and Skorokhod–Jakubowski a.s. representations of random variables in quasi-Polish spaces. The spatially dependent noise function constitutes a complication throughout the analysis, repeatedly giving rise to nonlinear terms that “balance” the martingale part of the equation against the second-order Stratonovich-to-Itô correction term. Finally, via pathwise uniqueness, we conclude that the constructed solutions are probabilistically strong. The uniqueness proof is based on a finite-dimensional Itô formula and a DiPerna–Lions type regularisation procedure, where the regularisation errors are controlled by first and second order commutators.

KW - Faedo–Galerkin method

KW - Shallow water equation

KW - Skorokhod–Jakubowski representation

KW - commutator estimate

KW - compactness

KW - convective noise

KW - existence

KW - stochastic perturbation

KW - tightness

KW - uniqueness

KW - viscous Camassa–Holm equation

UR - https://www.scopus.com/pages/publications/85146887453

U2 - 10.3934/dcds.2022163

DO - 10.3934/dcds.2022163

M3 - Article

AN - SCOPUS:85146887453

SN - 1078-0947

VL - 43

SP - 568

EP - 618

JO - Discrete and Continuous Dynamical Systems

JF - Discrete and Continuous Dynamical Systems

IS - 2

ER -

GLOBAL WELL-POSEDNESS OF THE VISCOUS CAMASSA–HOLM EQUATION WITH GRADIENT NOISE

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