A Modified Parameterization Method for Invariant Lagrangian Tori for Partially Integrable Hamiltonian Systems

Abstract

In this paper we present an a-posteriori KAM theorem for the existence of an (n-d)-parameters family of d-dimensional isotropic invariant tori with Diophantine frequency vector ω∈ Rd, of type (γ,τ), for n degrees of freedom Hamiltonian systems with (n-d) independent first integrals in involution. If the first integrals induce a Hamiltonian action of the (n-d)-dimensional torus, then we can produce n-dimensional Lagrangian tori with frequency vector of the form (ω,ωp), with ωp∈ Rn-d. In the light of the parameterization method, we design a (modified) quasi-Newton method for the invariance equation of the parameterization of the torus, whose proof of convergence from an initial approximation, and under appropriate non-degeneracy conditions, is the object of this paper. We present the results in the analytic category, so the initial torus is real-analytic in a certain complex strip of size , and the corresponding error in the functional equation is . We heavily use geometric properties and the so called automatic reducibility to deal directly with the functional equation and get convergence if γ-2 -2τ-1 is small enough, in contrast with most of KAM results based on the parameterization method, that get convergence if γ-4 -4τ is small enough. The approach is suitable to perform computer assisted proofs.