Non-integrability of the 1:1:2–resonance

J. J. Duistermaat

doi:10.1017/S0143385700002649

Abstract

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A Hamiltonian system of n degrees of freedom, defined by the function F, with an equilibrium point at the origin, is called formally integrable if there exist A A formal power series , functionally independent, in involution, and such that the Taylor expansion of F is a formal power series in the .

Take n = 3, , F(k) homogeneous of degree k, F(2) > 0 and the eigenfrequencies in ratio 1:1:2. If F(3) avoids a certain hypersurface of ‘symmetric’ third order terms, then the F system is not formally integrable. If F(3) is symmetric but F(4) is in a non-void open subset, then homoclinic intersection with Devaney spiralling occurs; the angle decays of order 1 when approaching the origin.

References

REFERENCES

[1]van der Aa, E. & Sanders, J.. The 1:2:1-resonance, its periodic orbits and integrals. Asymptotic Analysis, Springer Lecture Notes in Math. (Verhulst, , ed.) 711 (1979).Google Scholar

[2]Abraham, R. & Marsden, J. E.. Foundations of Mechanics, 2nd ed.Benjamin/Cummings, 1978.Google Scholar

[3]Devaney, R. L.. Homoclinic orbits in Hamiltonian systems. J. Diff. Eq. 21 (1976), 431–438.CrossRef Google Scholar

[4]Hánon, M. & Heiles, C.. The applicability of the third integral of motion: some numerical experiments. Astronom. J. 69 (1964), 73–79.Google Scholar

[5]Melnikov, V. K.. On the stability of the center for time periodic solutions. Trans. Moscow Math. Soc. 12 (1963), 3–56.Google Scholar

[6]Nilsson, N.. Some growth and ramification properties of certain integrals on algebraic manifolds. Ark. Mat. 5 (1965), 436–475.CrossRef Google Scholar

[7]Verhulst, F.. Asymptotic analysis in hamiltonian systems. Asymptotic Analysis II, Springer Lecture Notes in Math. 985 (1983), 137–193.Google Scholar

[8]Ziglin, S. L.. Branching of solutions and nonexistence of first integrals in Hamiltonian mechanics I. Fund. Anal, and its Appl. 16 (1982), 181–189; II, idem 17 (1983), 6–17.CrossRef Google Scholar

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Sanders, Jan A. and Verhulst, Ferdinand 1985. Averaging Methods in Nonlinear Dynamical Systems. Vol. 59, Issue. , p. 143.

Churchill, Richard C. and Rod, David L. 1986. Homoclinic and heteroclinic orbits of reversible vectorfields under perturbation. Proceedings of the Royal Society of Edinburgh: Section A Mathematics, Vol. 102, Issue. 3-4, p. 345.

Kummer, Martin 1987. The Physics of Phase Space Nonlinear Dynamics and Chaos Geometric Quantization, and Wigner Function. Vol. 278, Issue. , p. 63.

Hoveijn, Igor and Verhulst, Ferdinand 1990. Chaos in the 1:2:3 Hamiltonian normal form. Physica D: Nonlinear Phenomena, Vol. 44, Issue. 3, p. 397.

Kummer, Martin 1990. On resonant classical Hamiltonians with n frequencies. Journal of Differential Equations, Vol. 83, Issue. 2, p. 220.

Wan, Yieh-Hei 1992. Codimension two bifurcations of symmetric cycles in Hamiltonian systems with an antisymplectic involution. Journal of Dynamics and Differential Equations, Vol. 4, Issue. 2, p. 341.

Ito, Hidekazu 1992. Integrability of Hamiltonian systems and Birkhoff normal forms in the simple resonance case. Mathematische Annalen, Vol. 292, Issue. 1, p. 411.

Haller, George and Wiggins, Stephen 1996. Geometry and chaos near resonant equilibria of 3-DOF Hamiltonian systems. Physica D: Nonlinear Phenomena, Vol. 90, Issue. 4, p. 319.

Wang, L. Bosley, D.L. and Kevorkian, J. 1996. An asymptotic analysis of the 1:3:4 Hamiltonian normal form. Physica D: Nonlinear Phenomena, Vol. 99, Issue. 1, p. 1.

Palacián, Jesús and Yanguas, Patricia 2000. Reduction of polynomial Hamiltonians by the construction of formal integrals. Nonlinearity, Vol. 13, Issue. 4, p. 1021.

Ferrer, Sebastián Hanßmann, Heinz Palacián, Jesús and Yanguas, Patricia 2002. On perturbed oscillators in 1–1–1 resonance: the case of axially symmetric cubic potentials. Journal of Geometry and Physics, Vol. 40, Issue. 3-4, p. 320.

Palacián, Jesús and Yanguas, Patricia 2003. Equivariant N-Dof Hamiltonians Via Generalized Normal Forms. Communications in Contemporary Mathematics, Vol. 05, Issue. 03, p. 449.

Popov, A.A. 2004. The application of Hamiltonian dynamics and averaging to nonlinear shell vibration. Computers & Structures, Vol. 82, Issue. 31-32, p. 2659.

Vũ Ngọc, San 2008. The Quantum Birkhoff Normal Form and Spectral Asymptotics. Journées équations aux dérivées partielles, p. 1.

Sjamaar, Reyer 2011. Hans Duistermaat’s contributions to Poisson geometry. Bulletin of the Brazilian Mathematical Society, New Series, Vol. 42, Issue. 4, p. 783.

Christov, Ognyan 2012. Non-integrability of first order resonances in Hamiltonian systems in three degrees of freedom. Celestial Mechanics and Dynamical Astronomy, Vol. 112, Issue. 2, p. 149.

Verhulst, Ferdinand 2015. Integrability and Non-integrability of Hamiltonian Normal Forms. Acta Applicandae Mathematicae, Vol. 137, Issue. 1, p. 253.

Hanßmann, Heinz 2015. Perturbations of Superintegrable Systems. Acta Applicandae Mathematicae, Vol. 137, Issue. 1, p. 79.

Yamanaka, Shogo 2018. Local Integrability of Poincaré–Dulac Normal Forms. Regular and Chaotic Dynamics, Vol. 23, Issue. 7-8, p. 933.

Georgiev, Georgi 2019. Non-integrability of geodesic dynamics of Chazy-Curzon space-time. Vol. 2172, Issue. , p. 030001.

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Non-integrability of the 1:1:2–resonance

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