The cost rate of nonlinear remote stabilization on the Aubry--André lattice: a reflected off-spectral exponent and the sharp identity for almost every phase

Abstract

We study the exponential rate r(α,λ) of the energy EN needed to steer a far site, at distance N, of an Aubry--André chain Hλ via one boundary actuator with closed-loop margin α. An exact eigenbasis reduction writes EN as a Cauchy quadratic form b C-1 b in the boundary-amplitude ratios, whose rate is the off-spectral Lyapunov exponent of the transfer cocycle at the reflected band edge z=2E-2α-E, giving r(α,λ)=γλ(z). The rate lies in a bracket of width +(λ/2) whose ends coincide for λ2, the spectrum having logarithmic capacity (1,λ/2). We prove the identity unconditionally, for every phase, on the whole metallic--critical range 0<λ2: for λ<2 through subcritical almost reducibility as the sole external input, and at λ=2 because the Green's function there equals the Lyapunov exponent. For λ>2 the upper bound is unconditional, and the lower bound takes localization as its only external input: an inverse-free cocycle form makes EN a cancellation-free positive sum, and a Christoffel--Darboux identity collapses its coefficients to |ck|=Q(δk)(ψ(k)N)2, where band-edge near-degeneracies cancel. With a three-distance lemma this yields r=γλ(z) at every Diophantine frequency and almost every phase, with gap O(N-2/(2+τ)) for type τ (N-2/3 at bounded type), unconditionally for λλ1 and under a polynomial-prefactor localization hypothesis for 2<λ<λ1. The relative gap 1-r/γλ(z) vanishes at both ends of the localized phase, with gCΣλ(z)arccosh3 as λ∞.