Double Hamiltonian Hopf Bifurcation: normalization and normal form non-integrability

Abstract

The double Hamiltonian Hopf bifurcation is studied, i.e. a generic two-parametric unfolding of a smooth Hamiltonian system with four degrees of freedom which has at the critical value of parameters the equilibrium with two pairs of double non semi-simple pure imaginary eigenvalues iω1, iω2, ω1 ω2 under an assumption of absence of strong resonances between ω1,ω2. We derive the normal form of the unfolding, when the ratio ω1/ω2 is irrational and study the truncated normal form of the fourth order. This truncated normal form is the same under the absence of strong resonances. The normal form has two quadratic integrals generating a symplectic periodic action of the abelian group T2. After reduction by means of these integrals we come to the reduced system with two degrees of freedom that is proven to be non-integrable for almost all values of its coefficients. Integrable such systems are also possible at some special values of coefficients, related examples are presented. Some investigations of this truncated system are presented along with its bifurcations when varying small detuning parameters. As an example of a system where this bifurcation is met, the system derived in KuLe is investigated. Its homoclinic solutions are examined numerically when the system parameters correspond to a main equilibrium of the twofold saddle-focus type.