On solutions of Kolmogorov's equations for nonhomogeneous jump Markov processes

Eugene A. Feinberg; Manasa Mandava; Albert N. Shiryaev

doi:10.1016/j.jmaa.2013.09.043

On solutions of Kolmogorov's equations for nonhomogeneous jump Markov processes

Eugene A. Feinberg
, Manasa Mandava
, Albert N. Shiryaev

Applied Mathematics and Statistics

Stony Brook University
Steklov Mathematical Institute of RAS

Research output: Contribution to journal › Article › peer-review

23 Scopus citations

Abstract

This paper studies three ways to construct a nonhomogeneous jump Markov process: (i) via a compensator of the random measure of a multivariate point process, (ii) as a minimal solution of the backward Kolmogorov equation, and (iii) as a minimal solution of the forward Kolmogorov equation. The main conclusion of this paper is that, for a given measurable transition intensity, commonly called a Q-function, all these constructions define the same transition function. If this transition function is regular, that is, the probability of accumulation of jumps is zero, then this transition function is the unique solution of the backward and forward Kolmogorov equations. For continuous Q-functions, Kolmogorov equations were studied in Feller's seminal paper. In particular, this paper extends Feller's results for continuous Q-functions to measurable Q-functions and provides additional results.

Original language	English
Pages (from-to)	261-270
Number of pages	10
Journal	Journal of Mathematical Analysis and Applications
Volume	411
Issue number	1
DOIs	https://doi.org/10.1016/j.jmaa.2013.09.043
State	Published - Mar 1 2014

Keywords

Backward Kolmogorov equation
Compensator
Forward Kolmogorov equation
Jump Markov processes
Minimal non-negative solution
Transition function

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10.1016/j.jmaa.2013.09.043

Cite this

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title = "On solutions of Kolmogorov's equations for nonhomogeneous jump Markov processes",

abstract = "This paper studies three ways to construct a nonhomogeneous jump Markov process: (i) via a compensator of the random measure of a multivariate point process, (ii) as a minimal solution of the backward Kolmogorov equation, and (iii) as a minimal solution of the forward Kolmogorov equation. The main conclusion of this paper is that, for a given measurable transition intensity, commonly called a Q-function, all these constructions define the same transition function. If this transition function is regular, that is, the probability of accumulation of jumps is zero, then this transition function is the unique solution of the backward and forward Kolmogorov equations. For continuous Q-functions, Kolmogorov equations were studied in Feller's seminal paper. In particular, this paper extends Feller's results for continuous Q-functions to measurable Q-functions and provides additional results.",

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doi = "10.1016/j.jmaa.2013.09.043",

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AU - Feinberg, Eugene A.

AU - Mandava, Manasa

AU - Shiryaev, Albert N.

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N2 - This paper studies three ways to construct a nonhomogeneous jump Markov process: (i) via a compensator of the random measure of a multivariate point process, (ii) as a minimal solution of the backward Kolmogorov equation, and (iii) as a minimal solution of the forward Kolmogorov equation. The main conclusion of this paper is that, for a given measurable transition intensity, commonly called a Q-function, all these constructions define the same transition function. If this transition function is regular, that is, the probability of accumulation of jumps is zero, then this transition function is the unique solution of the backward and forward Kolmogorov equations. For continuous Q-functions, Kolmogorov equations were studied in Feller's seminal paper. In particular, this paper extends Feller's results for continuous Q-functions to measurable Q-functions and provides additional results.

AB - This paper studies three ways to construct a nonhomogeneous jump Markov process: (i) via a compensator of the random measure of a multivariate point process, (ii) as a minimal solution of the backward Kolmogorov equation, and (iii) as a minimal solution of the forward Kolmogorov equation. The main conclusion of this paper is that, for a given measurable transition intensity, commonly called a Q-function, all these constructions define the same transition function. If this transition function is regular, that is, the probability of accumulation of jumps is zero, then this transition function is the unique solution of the backward and forward Kolmogorov equations. For continuous Q-functions, Kolmogorov equations were studied in Feller's seminal paper. In particular, this paper extends Feller's results for continuous Q-functions to measurable Q-functions and provides additional results.

KW - Backward Kolmogorov equation

KW - Compensator

KW - Forward Kolmogorov equation

KW - Jump Markov processes

KW - Minimal non-negative solution

KW - Transition function

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DO - 10.1016/j.jmaa.2013.09.043

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EP - 270

JO - Journal of Mathematical Analysis and Applications

JF - Journal of Mathematical Analysis and Applications

IS - 1

ER -

On solutions of Kolmogorov's equations for nonhomogeneous jump Markov processes

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Keywords

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