Singular limit for a class of nonlocal conservation laws via compensated compactness
Abstract
We consider a class of nonlocal conservation laws modeling traffic flows, given by ∂t u + ∂x(V(u γ) u) = 0, with a rescaled convolution kernel γ(·) := -1γ(·/). We establish the strong L1loc-convergence of weak solutions u toward the entropy-admissible solution of the corresponding local conservation law as the kernel γ concentrates to a Dirac delta distribution when 0. In contrast to previous literature, we obtain compactness of the family \u γ\>0 without relying on total variation bounds or Olenik-type estimates. Instead, we establish L2-type bounds on its entropy production and use the theory of compensated compactness, assuming that the initial datum merely belongs to L1 L∞. Our results are twofold. First, we establish the nonlocal-to-local limit for the piecewise constant kernel γ(·) := 1[-1,0](·) combined with the affine velocity function from Greenshields' traffic model. Second, we prove the limit for strictly monotone kernels along with decreasing velocity functions. These results settle a long-standing open problem concerning the nonlocal-to-local convergence for non-convex kernels.
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