Fluctuation theory for spectrally positive additive L\'evy fields

Abstract

A spectrally positive additive L\'evy field is a multidimensional field obtained as the sum X t= X(1)t1+ X(2)t2+…+ X(d)td, t=(t1,…,td)∈R+d, where X(j)=t (X1,j,…,Xd,j), j=1,…,d, are d independent Rd-valued L\'evy processes issued from 0, such that Xi,j is non decreasing for i≠ j and Xj,j is spectrally positive. It can also be expressed as X t=X t 1, where 1=t(1,1,…,1) and X t=(Xi,jtj)1≤ i,j≤ d. The main interest of spaLf's lies in the Lamperti representation of multitype continuous state branching processes. In this work, we study the law of the first passage times T r of such fields at levels - r, where r∈R+d. We prove that the field \(T r,XT r), r∈R+d\ has stationary and independent increments and we describe its law in terms of this of the spaLf X. In particular, the Laplace exponent of (T r,XT r) solves a functional equation leaded by the Laplace exponent of X. This equation extends in higher dimension a classical fluctuation identity satisfied by the Laplace exponents of the ladder processes. Then we give an expression of the distribution of \(T r,XT r), r∈R+d\ in terms of the distribution of \X t, t∈R+d\ by the means of a Kemperman-type formula, well-known for spectrally positive L\'evy processes.