Integrable nonlinear oscillators with polynomial invariants: construction, Poincare geometry, and an analytic stability boundary
Abstract
Starting from the nonlinear ODE z'' + f(t)\,z + g(t)\, zm=0 with m>1, we show that after a suitable normal-form reduction of any Hill equation one may, without loss of generality, fix the linear part as f(t) ω2 (with ω>0 constant). For the class z''+ω2z+g(t)\, zm=0 with m>1, our goal is to compile a catalogue of all possible integrable cases. We restrict attention to integrals that are polynomial in the variables z and p=z'. The Hamiltonian does not provide such an integral because it is explicitly time dependent. Instead, we search for invariants that are quadratic in p=z'. We show that such invariants exist precisely when α2(t):=g(t)-2/(m+3) satisfies the linear third-order ODE α2''' + 4ω2 α2'=0. This yields the three-parameter solution g(t)=[a0+a1(2ω t)+a2(2ω t)]-(m+3)/2. For m=2 this reproduces the trigonometric structure with exponent -5/2 found in Hagel--Bouquet (1992). In addition we present a detailed stability analysis based on the invariant using Poincar\'e sections and find full agreement with numerical simulations.
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