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Section: New Results

An increment type set-indexed Markov property

Participant : Paul Balança.

[1] investigates a new approach for the definition of a set-indexed Markov property, named $𝒞$ -Markov. The study is based on Merzbach and Ivanoff's set-indexed formalism, i.e. $𝒜$ denotes a set-indexed collection and $𝒞$ the family of increments $C = A ∖ B$ , where $A \in 𝒜$ and $B \in 𝒜 (u)$ (finite unions of sets from $𝒜$ ). Moreover, for any $C = A ∖ B$ , $B = \cup_{i = 1}^{k} A_{i}$ , $𝒜_{𝐂}$ is defined as the following subset of $𝒜$ :

𝒜_{𝐂} = {U \in 𝒜_{ℓ}; U ⊈ B^{\circ}} : = {U_{C}^{1}, \dots, U_{C}^{p}}, where p = | 𝒜_{𝐂} |

and $𝒜_{ℓ}$ corresponds to the semilattice ${A_{1} \cap \dots \cap A_{k}, \dots, A_{1} \cap A_{2}, A_{1} \dots, A_{k}} \subset 𝒜$ . The notation $𝐗_{𝐂}$ refers to a random vector $𝐗_{𝐂} = (X_{U_{C}^{1}}, \dots, X_{U_{C}^{p}})$ . Similarly, $𝐱_{𝐂}$ is used to denote a vector of variables $(x_{U_{C}^{1}}, \dots, x_{U_{C}^{p}})$ .

Then, an $E$ -valued set-indexed process ${(X_{A})}_{A \in 𝒜}$ is said to be $𝒞$ -Markov with respect to a filtration ${(ℱ_{A})}_{A \in 𝒜}$ if it is adapted to ${(ℱ_{A})}_{A \in 𝒜}$ and if it satisfies

𝔼 [f (X_{A}) | 𝒢_{C}^{*}] = 𝔼 [f (X_{A}) | 𝐗_{𝐂}] ℙ -a.s.

(7)

for all $C = A ∖ B \in 𝒞$ and any bounded measurable function $f : E \to 𝐑$ . The sigma-algebra $𝒢_{C}^{*}$ is usually called the strong history of ${(ℱ_{A})}_{A \in 𝒜}$ and is defined as $𝒢_{C}^{*} = ⋁_{A \in 𝒜, A \cap C = \emptyset} ℱ_{A}$ .

The $𝒞$ -Markov approach has several advantages compared to existing set-indexed Markov literature (mainly $𝒬$ -Markov described in [48] ). It appears to be a natural extension of the classic one-parameter Markov property. In particular, the concept of transition system can easily extended to our formalism: for any $𝒞$ -Markov process $X$ , one can defined $𝒫 = {P_{C} (𝐱_{𝐂}; d x_{A}); C \in 𝒞}$ as

\forall 𝐱_{𝐂} \in E^{| 𝒜_{𝐂} |}, Γ \in ℰ; P_{C} (𝐱_{𝐂}; Γ) : = ℙ (X_{A} \in Γ | 𝐗_{𝐂} = 𝐱_{𝐂}) .

A $𝒞$ -transition system $𝒫$ happens to satisfy a set-indexed Chapman-Kolmogorov equation,

\forall C \in 𝒞, A^{'} \in 𝒜; P_{C} f = P_{C^{'}} P_{C^{''}} f where C^{'} = C \cap A^{'}, C^{''} = C ∖ A^{'}

(8)

and $f$ is a bounded measurable function.

Similarly to the classic Markovian theory, is is proved in [1] that the initial distribution $μ$ and $𝒫$ characterize entirely the law of a $𝒞$ -Markov process, and that conversely, for any initial law and any $𝒞$ -transition system, a corresponding canonical set-indexed $𝒞$ -Markov process can be constructed. $𝒞$ -Markov processes enjoy several other properties such as

Projections on elementary flows are Markovian;
Conditional independence of natural filtrations;
Strong Markov property.

The class of set-indexed Lévy processes defined and studied in [21] offers examples of $𝒞$ -Markov processes whose transition probabilities correspond to

\forall C = A ∖ B \in 𝒞, \forall Γ \in ℰ; P_{C} (𝐱_{𝐂}; Γ) = μ^{m (C)} (Γ - Δ x_{B}),

(9)

where $m$ is a measure on $𝒯$ and $μ$ the infinitely divisible probability measure that characterizes the Lévy process. We note that the transition system related the $𝒬$ -Markov property has a different form, even if it is related.

Another non-trivial example of $𝒞$ -Markov process is the set-indexed Ornstein-Uhlenbeck process that has been introduced and studied in [32] . It is a Gaussian Markovian process whose transition densities are given by

p_{C} (𝐱_{𝐂}; y) = \frac{1}{σ_{C} \sqrt{2 π}} exp [- \frac{1}{2 σ_{C}^{2}} {(y - e^{- λ m (A)} [\sum_{i = 1}^{n} {(- 1)}^{ε_{i}} x_{U_{C}^{i}} e^{λ m (U_{C}^{i})}])}^{2}],

(10)

where $λ$ and $σ$ are positive parameters, $m$ is a measure on $𝒯$ and

σ_{C}^{2} = \frac{σ^{2}}{2 λ} (1 - e^{- 2 λ m (A)} [\sum_{i = 1}^{n} {(- 1)}^{ε_{i}} e^{2 λ m (U_{C}^{i})}]) .

In the particular case of multiparameter processes, corresponding to the indexing collection $𝒜 = {[0, t]; t \in 𝐑_{+}^{N}}$ , the $𝒞$ -Markov formalism is related to several existing works. It generalizes the two-parameter $*$ -Markov property introduced in [53] and also embraces the multiparameter Markov property investigated recently in [68] . Finally, under some Feller assumption on the transition system, a multiparameter $𝒞$ -Markov process is proved to admit a modification with right-continuous sample paths.

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