Markov operator

In probability theory and ergodic theory, a Markov operator is an operator on a certain function space that conserves the mass (the so-called Markov property). If the underlying measurable space is topologically sufficiently rich enough, then the Markov operator admits a kernel representation. Markov operators can be linear or non-linear. Closely related to Markov operators is the Markov semigroup.^[1]

The definition of Markov operators is not entirely consistent in the literature. Markov operators are named after the Russian mathematician Andrey Markov.

Definitions[edit]

Markov operator[edit]

Let $(E,{\mathcal {F}})$ be a measurable space and $V$ a set of real, measurable functions $f:(E,{\mathcal {F}})\to (\mathbb {R} ,{\mathcal {B}}(\mathbb {R} ))$ .

A linear operator $P$ on $V$ is a Markov operator if the following is true^[1]^: 9–12

$P$ maps bounded, measurable function on bounded, measurable functions.
Let $\mathbf {1}$ be the constant function $x\mapsto 1$ , then $P(\mathbf {1} )=\mathbf {1}$ holds. (conservation of mass / Markov property)
If $f\geq 0$ then $Pf\geq 0$ . (conservation of positivity)

Alternative definitions[edit]

Some authors define the operators on the L^p spaces as $P:L^{p}(X)\to L^{p}(Y)$ and replace the first condition (bounded, measurable functions on such) with the property^[2]^[3]

\|Pf\|_{Y}=\|f\|_{X},\quad \forall f\in L^{p}(X)

Markov semigroup[edit]

Let ${\mathcal {P}}=\{P_{t}\}_{t\geq 0}$ be a family of Markov operators defined on the set of bounded, measurables function on $(E,{\mathcal {F}})$ . Then ${\mathcal {P}}$ is a Markov semigroup when the following is true^[1]^: 12

$P_{0}=\operatorname {Id}$ .
$P_{t+s}=P_{t}\circ P_{s}$ for all $t,s\geq 0$ .
There exist a σ-finite measure $\mu$ on $(E,{\mathcal {F}})$ that is invariant under ${\mathcal {P}}$ , that means for all bounded, positive and measurable functions $f:E\to \mathbb {R}$ and every $t\geq 0$ the following holds

\int _{E}P_{t}f\mathrm {d} \mu =\int _{E}f\mathrm {d} \mu

.

Dual semigroup[edit]

Each Markov semigroup ${\mathcal {P}}=\{P_{t}\}_{t\geq 0}$ induces a dual semigroup $(P_{t}^{*})_{t\geq 0}$ through

\int _{E}P_{t}f\mathrm {d\mu } =\int _{E}f\mathrm {d} \left(P_{t}^{*}\mu \right).

If $\mu$ is invariant under ${\mathcal {P}}$ then $P_{t}^{*}\mu =\mu$ .

Infinitesimal generator of the semigroup[edit]

Let $\{P_{t}\}_{t\geq 0}$ be a family of bounded, linear Markov operators on the Hilbert space $L^{2}(\mu )$ , where $\mu$ is an invariant measure. The infinitesimale generator $L$ of the Markov semigroup ${\mathcal {P}}=\{P_{t}\}_{t\geq 0}$ is defined as

Lf=\lim \limits _{t\downarrow 0}{\frac {P_{t}f-f}{t}},

and the domain $D(L)$ is the $L^{2}(\mu )$ -space of all such functions where this limit exists and is in $L^{2}(\mu )$ again.^[1]^: 18^[4]

D(L)=\left\{f\in L^{2}(\mu ):\lim \limits _{t\downarrow 0}{\frac {P_{t}f-f}{t}}{\text{ exists and is in }}L^{2}(\mu )\right\}.

The carré du champ operator $\Gamma$ measuers how far $L$ is from being a derivation.

Kernel representation of a Markov operator[edit]

A Markov operator $P_{t}$ has a kernel representation

(P_{t}f)(x)=\int _{E}f(y)p_{t}(x,\mathrm {d} y),\quad x\in E,

with respect to some probability kernel $p_{t}(x,A)$ , if the underlying measurable space $(E,{\mathcal {F}})$ has the following sufficient topological properties:

Each probability measure $\mu :{\mathcal {F}}\times {\mathcal {F}}\to [0,1]$ can be decomposed as $\mu (\mathrm {d} x,\mathrm {d} y)=k(x,\mathrm {d} y)\mu _{1}(\mathrm {d} x)$ , where $\mu _{1}$ is the projection onto the first component and $k(x,\mathrm {d} y)$ is a probability kernel.
There exist a countable family that generates the σ-algebra ${\mathcal {F}}$ .

If one defines now a σ-finite measure on $(E,{\mathcal {F}})$ then it is possible to prove that ever Markov operator $P$ admits such a kernel representation with respect to $k(x,\mathrm {d} y)$ .^[1]^: 7–13

Literature[edit]

Bakry, Dominique; Gentil, Ivan; Ledoux, Michel. Analysis and Geometry of Markov Diffusion Operators. Springer Cham. doi:10.1007/978-3-319-00227-9.
Eisner, Tanja; Farkas, Bálint; Haase, Markus; Nagel, Rainer (2015). "Markov Operators". Operator Theoretic Aspects of Ergodic Theory. Graduate Texts in Mathematics. Vol. 2727. Cham: Springer. doi:10.1007/978-3-319-16898-2.
Wang, Fengyu (2006). Functional Inequalities Markov Semigroups and Spectral Theory. Ukraine: Elsevier Science.

References[edit]

^ ^a ^b ^c ^d ^e Bakry, Dominique; Gentil, Ivan; Ledoux, Michel. Analysis and Geometry of Markov Diffusion Operators. Springer Cham. doi:10.1007/978-3-319-00227-9.
^ Eisner, Tanja; Farkas, Bálint; Haase, Markus; Nagel, Rainer (2015). "Markov Operators". Operator Theoretic Aspects of Ergodic Theory. Graduate Texts in Mathematics. Vol. 2727. Cham: Springer. p. 249. doi:10.1007/978-3-319-16898-2.
^ Wang, Fengyu (2006). Functional Inequalities Markov Semigroups and Spectral Theory. Ukraine: Elsevier Science. p. 3.
^ Wang, Fengyu (2006). Functional Inequalities Markov Semigroups and Spectral Theory. Ukraine: Elsevier Science. p. 1.

[BGL-1] Bakry, Dominique; Gentil, Ivan; Ledoux, Michel. Analysis and Geometry of Markov Diffusion Operators. Springer Cham. doi:10.1007/978-3-319-00227-9.

[2] Eisner, Tanja; Farkas, Bálint; Haase, Markus; Nagel, Rainer (2015). "Markov Operators". Operator Theoretic Aspects of Ergodic Theory. Graduate Texts in Mathematics. Vol. 2727. Cham: Springer. p. 249. doi:10.1007/978-3-319-16898-2.

[3] Wang, Fengyu (2006). Functional Inequalities Markov Semigroups and Spectral Theory. Ukraine: Elsevier Science. p. 3.

[4] Wang, Fengyu (2006). Functional Inequalities Markov Semigroups and Spectral Theory. Ukraine: Elsevier Science. p. 1.

[1]

[2]

[3]

[4]