2001
DOI: 10.4310/ajm.2001.v5.n3.a3
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A generalized index theorem for Morse–Sturm systems and applications to semi-Riemannian geometry

Abstract: ABSTRACT. We prove an extension of the Index Theorem for Morse-Sturm systems of the form −V ′′ + RV = 0, where R is symmetric with respect to a (non positive) symmetric bilinear form, and thus the corresponding differential operator is not self-adjoint. The result is then applied to the case of a Jacobi equation along a geodesic in a Lorentzian manifold, obtaining an extension of the Morse Index Theorem for Lorentzian geodesics with variable initial endpoints. Given a Lorentzian manifold (M, g), we consider a … Show more

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Cited by 24 publications
(41 citation statements)
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“…(f) If an instant t 0 ∈ ]0, 1[ is a jump instant for µ, then t 0 is a focal instant along γ. This follows from the main result of [10], since the P-Maslov of γ has jumps only at the focal instants. Thus, µ is constant on every interval that does not contain focal instants.…”
Section: Evolution Of the Index Functions And The Distribution Of Focmentioning
confidence: 60%
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“…(f) If an instant t 0 ∈ ]0, 1[ is a jump instant for µ, then t 0 is a focal instant along γ. This follows from the main result of [10], since the P-Maslov of γ has jumps only at the focal instants. Thus, µ is constant on every interval that does not contain focal instants.…”
Section: Evolution Of the Index Functions And The Distribution Of Focmentioning
confidence: 60%
“…Using the theory developed in this paper and some results in the recent literature, we can now summarize a few facts about the distribution of focal and pseudo focal instants along a geodesic. (d) µ(t) is equal to the P-Maslov index of γ| [0,t] , as proved in [10].…”
Section: Evolution Of the Index Functions And The Distribution Of Focmentioning
confidence: 87%
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“…This is a symplectic invariant, which is computed as an intersection number in the Lagrangian Grasmannian of a symplectic vector space. Details on the definition and the computation of the Maslov index for a given geodesic γ, that will be denoted by i Maslov (γ) can be found in [15,16,22].…”
Section: Computation Of the Spectral Flowmentioning
confidence: 99%