On the vanishing discount approximation for compactly supported perturbations of periodic Hamiltonians: the 1d case

Abstract

We study the asymptotic behavior of the viscosity solutions uλG of the Hamilton-Jacobi (HJ) equation equation* λ u(x)+G(x,u')=c(G)in R equation* as the positive discount factor λ tends to 0, where G(x,p):=H(x,p)-V(x) is the perturbation of a Hamiltonian H∈ C( R× R), Z-periodic in the space variable and convex and coercive in the momentum, by a compactly supported potential V∈ Cc( R). The constant c(G) appearing above is defined as the infimum of values a∈ R for which the HJ equation G(x,u')=a in R admits bounded viscosity subsolutions. We prove that the functions uλG locally uniformly converge, for λ→ 0+, to a specific solution uG0 of the critical equation equationabs* G(x,u')=c(G)in R. equation We identify u0G in terms of projected Mather measures for G and of the limit u0H to the unperturbed periodic problem. This can be regarded as an extension to a noncompact setting of the main results in [17]. Our work also includes a qualitative analysis of abs with a weak KAM theoretic flavor.

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