Kinetic description of scalar conservation laws with Markovian data

Abstract

We derive a kinetic equation to describe the statistical structure of solutions to scalar conservation laws t=H(x,t, )x, with certain Markov initial conditions. When the Hamiltonian function is convex and increasing in , we show that the solution (x,t) is a Markov process in x (respectively t) with t (respectively x) fixed. Two classes of Markov conditions are considered in this article. In the first class, the initial data is characterize by a drift b which satisfies a linear PDE, and a jump density f which satisfies a kinetic equation as time varies. In the second class, the initial data is a concatenation of fundamental solutions that are characterized by a parameter y, which is a Markov jump process with a jump density g satisfying a kinetic equation. When H is not increasing in , the restriction of to a line in (x,t) plane is a Markov process of the same type, provided that the slope of the line satisfies an inequality.