Multiple and weak Markov properties in Hilbert spaces with applications to fractional stochastic evolution equations

We define a number of higher-order Markov properties for stochastic processes (X(t))t∈T, indexed by an interval T⊆R and taking values in a real and separable Hilbert space U. We furthermore investigate the relations between them. In particular, for solutions to the stochastic evolution equation LX=W...

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Veröffentlicht in:Stochastic processes and their applications Jg. 186; S. 104639
Hauptverfasser: Kirchner, Kristin, Willems, Joshua
Format: Journal Article
Sprache:Englisch
Veröffentlicht: Elsevier B.V 01.08.2025
Schlagworte:
Higher-order Markov property
Infinite-dimensional fractional Wiener process
Matérn covariance
Spatiotemporal Gaussian process
Higher-order Markov property
60G22
35R60
Infinite-dimensional fractional Wiener process
Matérn covariance
60J25
Spatiotemporal Gaussian process
60G15
ISSN:0304-4149, 1879-209X
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Beschreibung
Zusammenfassung:We define a number of higher-order Markov properties for stochastic processes (X(t))t∈T, indexed by an interval T⊆R and taking values in a real and separable Hilbert space U. We furthermore investigate the relations between them. In particular, for solutions to the stochastic evolution equation LX=Ẇ, where L is a linear operator acting on functions mapping from T to U and (Ẇ(t))t∈T is the formal derivative of a U-valued cylindrical Wiener process, we prove necessary and sufficient conditions for the weakest Markov property via locality of the precision operator L∗L. As an application, we consider the space–time fractional parabolic operator L=(∂t+A)γ of order γ∈(1/2,∞), where −A is a linear operator generating a C0-semigroup on U. We prove that the resulting solution process satisfies an Nth order Markov property if γ=N∈N and show that a necessary condition for the weakest Markov property is generally not satisfied if γ∉N. The relevance of this class of processes is twofold: Firstly, it can be seen as a spatiotemporal generalization of Whittle–Matérn Gaussian random fields if U=L2(D) for a spatial domain D⊆Rd. Secondly, we show that a U-valued analog to the fractional Brownian motion with Hurst parameter H∈(0,1) can be obtained as the limiting case of L=(∂t+ɛIdU)H+12 for ɛ↓0.
ISSN:0304-4149
1879-209X
DOI:10.1016/j.spa.2025.104639