Asymptotically compatible entropy-consistent discretization for a class of nonlocal conservation laws

Abstract

We consider a class of nonlocal conservation laws modeling traffic flows, given by ∂t + ∂x(V( γ) ) = 0 with a suitable convex kernel γ , and its Godunov-type numerical discretization. We prove that, as the nonlocal parameter and mesh size h tend to zero simultaneously, the discrete approximation W,h of W := γ converges to the entropy solution of the (local) scalar conservation law ∂t + ∂x(V() ) = 0 , with an explicit convergence rate estimate of order +h+\, t+h\,t . In particular, with an exponential kernel, we establish the same convergence result for the discrete approximation ,h of , along with an L1 -contraction property for W . The key ingredients in proving these results are uniform L∞ - and TV-estimates that ensure compactness of approximate solutions, and discrete entropy inequalities that ensure the entropy admissibility of the limit solution.