Finite or countable state space for J(t) edit

The process ${\displaystyle \{(X(t),J(t)):t\geq 0\}}$  is a Markov additive process with continuous time parameter t if^[1]

1. ${\displaystyle \{(X(t),J(t));t\geq 0\}}$  is a Markov process
2. the conditional distribution of ${\displaystyle (X(t+s)-X(t),J(t+s))}$  given ${\displaystyle (X(t),J(t))}$  depends only on ${\displaystyle J(t)}$ .

The state space of the process is R × S where X(t) takes real values and J(t) takes values in some countable set S.

General state space for J(t) edit

For the case where J(t) takes a more general state space the evolution of X(t) is governed by J(t) in the sense that for any f and g we require^[2]

${\displaystyle \mathbb {E} [f(X_{t+s}-X_{t})g(J_{t+s})|{\mathcal {F}}_{t}]=\mathbb {E} _{J_{t},0}[f(X_{s})g(J_{s})]}$ .

A fluid queue is a Markov additive process where J(t) is a continuous-time Markov chain^{[clarification needed][example needed]}.

Çinlar uses the unique structure of the MAP to prove that, given a gamma process with a shape parameter that is a function of Brownian motion, the resulting lifetime is distributed according to the Weibull distribution.

Kharoufeh presents a compact transform expression for the failure distribution for wear processes of a component degrading according to a Markovian environment inducing state-dependent continuous linear wear by using the properties of a MAP and assuming the wear process to be temporally homogeneous and that the environmental process has a finite state space.