Convergence of the solutions of the discounted Hamilton–Jacobi equation

Abstract: International audienceWe consider a continuous coercive Hamiltonian H on the cotangent bundle of the compact connected manifold M which is convex in the momentum. If uλ:M→ℝ is the viscosity solution of the discounted equationλuλ(x)+H(x,dxuλ)=c(H),where c(H) is the critical value, we prove that uλ converges uniformly, as λ→0, to a specific solution u0:M→ℝ of the critical equationH(x,dxu)=c(H).We characterize u0in terms of Peierls barrier and projected Mather measures. As a corollary, we infer that the ergodic a… Show more

“…this maximum does exist in force of (A3). The function u ≡ − b λ is subsolution to (DP) for any λ > 0, so that λ u λ ≥ −b, and accordingly (7) 0…”

“…Further, due to H ≥ H, any subsolution of λ u + H[u] is also subsolution to (DP), which implies that the maximal subsolution to λ u + H[u] = 0 is less than or equal to u λ . On the other side, since by (7) H(x, Du λ (x)) = H(x, Du λ (x)) for a.e. x the function u λ itself is subsolution to λ u + H[u] = 0.…”

“…As in [7], we derive the asymptotic behavior of solutions from weak convergence of suitable associated measures. Our method however is rather different.…”

The vanishing discount problem for Hamilton–Jacobi equations in the Euclidean space

“…this maximum does exist in force of (A3). The function u ≡ − b λ is subsolution to (DP) for any λ > 0, so that λ u λ ≥ −b, and accordingly (7) 0…”

“…Further, due to H ≥ H, any subsolution of λ u + H[u] is also subsolution to (DP), which implies that the maximal subsolution to λ u + H[u] = 0 is less than or equal to u λ . On the other side, since by (7) H(x, Du λ (x)) = H(x, Du λ (x)) for a.e. x the function u λ itself is subsolution to λ u + H[u] = 0.…”

“…As in [7], we derive the asymptotic behavior of solutions from weak convergence of suitable associated measures. Our method however is rather different.…”

The vanishing discount problem for Hamilton–Jacobi equations in the Euclidean space

“…Hamilton-Jacobi equations in [8] (first-order case), [1] (first-order case with Neumanntype boundary condition), [20] (degenerate viscous case). In the case of first-order equations [1,8], optimal control formulas are used and the Mather measures, introduced and developed in [18,19], play a central role.…”

“…In the case of first-order equations [1,8], optimal control formulas are used and the Mather measures, introduced and developed in [18,19], play a central role. The proof in [20] for a degenerate viscous case is based on the nonlinear adjoint method, stochastic Mather measures and a regularization procedure by mollifications to handle the delicate viscous term using a commutation lemma.…”

The vanishing discount problem and viscosity Mather measures. Part 1: The problem on a torus

Herglotz’ Generalized Variational Principle and Contact Type Hamilton-Jacobi Equations