Interpretation of run-and-tumble motion as jump-process: the case of a harmonic trap

By mapping run-and-tumble motion onto jump-process (a process in which a particle, instead of moving continuously in time, performs consequential jumps), a system in a steady-state can be formulated as an integral equation. The key ingredient of this formulation is the transition operator $G(x,x')$, representing the probability distribution of jumps along the $x$-axis for a particle located at $x'$ before a jump. For particles in a harmonic trap, exact expressions for $G(x,x')$ are obtained and, in principle, $G(x,x')$ has all the information about a stationary distribution $\rho(x)$. One way to extract $\rho$ is to use the condition of stationarity, $\rho(x) = \int dx' \, \rho(x') G(x,x')$, resulting in an integral equation formulation of the problem. For the system in dimension $d=2$, there is an unexpected reduction of complexity; the expression for $G(x,x')$ is found to be reversible, which implies that $\rho(x)$ (within the jump-process interpretation) obeys the detailed balance condition, and $\rho$ can be obtained from the detailed balance relation, $\rho(x') G(x,x') = \rho(x) G(x',x)$.