Representation of Global Viscosity Solutions for Tonelli Hamiltonians
Abstract
We consider the Lax-Oleinik operator T associated with the non-stationary Hamilton-Jacobi equation ∂tu + H(t,x,∂xu) = α0 for a Tonelli Hamiltonian H and its critical value α0. It is known from the work of A. Fathi and J.N. Mather MR1792479 that the convergence of this semigroup fails in the non-autonomous framework. In this context, we study the action of T on its non-wandering set (T). First, we show that T acts as an isometry on this set, and then we characterize (T) as the set of global viscosity solutions of the Hamilton-Jacobi equation, i.e. solutions that are defined for all real times. Next, we introduce a generalized Peierls barrier k and a set of generalized static classes M within the Mather set. Using these, we represent elements u of (T) as equation* u(x) = ∈fy ∈ M \ u(y) + k(y,x) \ equation* We apply this representation formula to prove Fathi's convergence theorem for autonomous systems and provide a representation formula for n-periodic viscosity solutions. Additionally, we establish that the dynamics of non-wandering viscosity solutions are governed by the Lagrangian flow on the Mather set. Specifically, we show that if the Mather set consists solely of N-periodic orbits for some integer N, then all non-wandering viscosity solutions are N-periodic. Furthermore, we show that if the restriction of the Lagrangian flow to the Mather set is uniformly recurrent for a time sequence pn, then all non-wandering viscosity solutions are uniformly recurrent for the same time sequence pn.
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