The one-sided Lipschitz condition in the follow-the-leader approximation of scalar conservation laws

Abstract

We consider the follow-the-leader particle approximation scheme for a 1d scalar conservation law with nonnegative L∞c initial datum and with a C1 concave flux, which is known to provide convergence towards the entropy solution to the corresponding Cauchy problem. We provide two novel contributions to this theory. First, we prove that the one-sided Lipschitz condition satisfied by the approximating density n is a discrete version of an entropy condition; more precisely, under fairly general assumptions on f (which imply concavity of f) we prove that the continuum version (f()/)x≤ 1/t of said condition allows to select a unique weak solution, despite (f()/)x≤ 1/t is apparently weaker than the classical Oleinik-Hoff one-sided Lipschitz condition f'()x≤ 1/t. Said result relies on an improved version of Hoff's uniqueness proof. A byproduct of it is that the entropy condition is encoded in the particle scheme prior to the many-particle limit, which was never proven before. Second, we prove that in case f()=(A-γ) the one-sided Lipschitz condition can be improved to a discrete version of the classical (and sharp) Oleinik-Hoff condition. In order to make the paper self-contained, we provide proofs (in some cases alternative ones) of all steps of the convergence of the particle scheme.