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Trace formula for linear Hamiltonian systems with its applications to elliptic Lagrangian solutions. (English) Zbl 1316.35276

Authors’ abstract: In the present paper, we build up trace formulas for both the linear Hamiltonian systems and Sturm-Liouville systems. The formula connects the monodromy matrix of a symmetric periodic orbit with the infinite sum of eigenvalues of the Hessian of the action functional. A natural application is to study the non-degeneracy of linear Hamiltonian systems. Precisely, by the trace formula, we can give an estimation for the upper bound such that the non-degeneracy preserves. Moreover, we could estimate the relative Morse index by the trace formula. Consequently, a series of new stability criteria for the symmetric periodic orbits is given. As a concrete application, the trace formula is used to study the linear stability of elliptic Lagrangian solutions of the classical planar three-body problem, which depends on the mass parameter \({\beta \in [0,9]}\) and the eccentricity \(e \in [0,1)\). Based on the trace formula, we estimate the stable region and hyperbolic region of the elliptic Lagrangian solutions.

MSC:

35Q70 PDEs in connection with mechanics of particles and systems of particles
70F10 \(n\)-body problems
35B10 Periodic solutions to PDEs
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