Fluctuation theory for level-dependent L\'evy risk processes

Abstract

A level-dependent L\'evy process solves the stochastic differential equation dU(t) = dX(t)-φ(U(t)) dt, where X is a spectrally negative L\'evy process. A special case is a multi-refracted L\'evy process with φk(x)=Σj=1kδj1\x≥ bj\. A general rate function φ that is non-decreasing and continuously differentiable is also considered. We discuss solutions of the above stochastic differential equation and investigate the so-called scale functions, which are counterparts of the scale functions from the theory of L\'evy processes. We show how fluctuation identities for U can be expressed via these scale functions. We demonstrate that the derivatives of the scale functions are solutions of Volterra integral equations.