In this paper, we investigate the problem of the existence and multiplicity of periodic solutions to the planar Hamiltonian system x =-α(t)f (y), y = β(t)g(x), where α, β are non-negative T-periodic coefficients and 0. We focus our study to the so-called "degenerate"situation, namely when the set Z := supp α supp β has Lebesgue measure zero. It is known that, in this case, for some choices of α and β, no nontrivial T-periodic solution exists. On the opposite, we show that, depending of some geometric configurations of α and β, the existence of a large number of T-periodic solutions (aswell as subharmonic solutions) is guaranteed (for 0 and large). Our proof is based on the Poincare Birkhoff twist theorem. Applications are given to Volterra s predator-prey model with seasonal effects.
The Poincaré-Birkhoff Theorem for a Class of Degenerate Planar Hamiltonian Systems
Zanolin F.;
2021-01-01
Abstract
In this paper, we investigate the problem of the existence and multiplicity of periodic solutions to the planar Hamiltonian system x =-α(t)f (y), y = β(t)g(x), where α, β are non-negative T-periodic coefficients and 0. We focus our study to the so-called "degenerate"situation, namely when the set Z := supp α supp β has Lebesgue measure zero. It is known that, in this case, for some choices of α and β, no nontrivial T-periodic solution exists. On the opposite, we show that, depending of some geometric configurations of α and β, the existence of a large number of T-periodic solutions (aswell as subharmonic solutions) is guaranteed (for 0 and large). Our proof is based on the Poincare Birkhoff twist theorem. Applications are given to Volterra s predator-prey model with seasonal effects.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
