Addenda and corrections to work done on the path-integral approach to classical mechanics

In this paper we continue the study of the path-integral formulation of classical mechanics and in particular we better clarify, with respect to previous papers, the geometrical meaning of the variables entering this formulation. With respect to the first paper with the same title, we {\it correct}...

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Bibliographic Details
Published in:arXiv.org 2000-08
Main Authors: Gozzi, E, Regini, M
Format: Article
Language:English
Subjects:
Bundling
Classical mechanics
Integrals
Mechanics (physics)
Transformations
Online Access:Get full text
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Summary:In this paper we continue the study of the path-integral formulation of classical mechanics and in particular we better clarify, with respect to previous papers, the geometrical meaning of the variables entering this formulation. With respect to the first paper with the same title, we {\it correct} here the set of transformations for the auxiliary variables \(\lambda_{a}\). We prove that under this new set of transformations the Hamiltonian \({\widetilde{\cal H}}\), appearing in our path-integral, is an exact scalar and the same for the Lagrangian. Despite this different transformation, the variables \(\lambda_{a}\) maintain the same operatorial meaning as before but on a different functional space. Cleared up this point we then show that the space spanned by the whole set of variables (\(\phi, c, \lambda,\bar c\)) of our path-integral is the cotangent bundle to the {\it reversed-parity} tangent bundle of the phase space \({\cal M}\) of our system and it is indicated as \(T^{\star}(\Pi T{\cal M})\). In case the reader feel uneasy with this strange {\it Grassmannian} double bundle, we show in this paper that it is possible to build a different path-integral made only of {\it bosonic} variables. These turn out to be the coordinates of \(T^{\star}(T^{\star}{\cal M})\) which is the double cotangent bundle of phase-space.
ISSN:2331-8422
DOI:10.48550/arxiv.9903136