A Volterra equation approach to the local limit of nonlocal traffic models
Abstract
We consider a class of nonlocal conservation laws modeling traffic flow, given by ∂t u + ∂x(V(u γ)\, u) = 0 with γ(·) := -1γ(·/) for a suitable convex convolution kernel γ. Since the work of Colombo et al. (Arch. Ration. Mech. Anal., 2023), thanks to uniform L∞ - and TV-estimates, it is known that w := u γ converges to the entropy solution of the local scalar conservation law ∂t u + ∂x(V(u)\, u) = 0 as 0. However, the convergence of \u\ > 0 itself has not been fully addressed so far. In this direction, a known result applies specifically to the case of an exponential kernel, where the identity ∂x w = w - u is fundamental. In this work, we address this gap in the literature and prove that \u\ > 0 converges to the same limit u under the mild additional assumption that the initial datum belongs to L1(R). Our analysis exploits, through a Fourier approach, the stability properties of the more general Volterra-type equation ∂xw=γ' u-γ(0)u, thereby deducing the convergence of u from that of w.
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