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Singular Lagrangians, Constrained Hamiltonian Systems and Gauge Invariance: An Example of the Dirac–Bergmann Algorithm

J. Brown

2022Universe16 citationsDOIOpen Access PDF

Abstract

The Dirac–Bergmann algorithm is a recipe for converting a theory with a singular Lagrangian into a constrained Hamiltonian system. Constrained Hamiltonian systems include gauge theories—general relativity, electromagnetism, Yang–Mills, string theory, etc. The Dirac–Bergmann algorithm is elegant but at the same time rather complicated. It consists of a large number of logical steps linked together by a subtle chain of reasoning. Examples of the Dirac–Bergmann algorithm found in the literature are designed to isolate and illustrate just one or two of those logical steps. In this paper, I analyze a finite-dimensional system that exhibits all of the major steps in the algorithm. The system includes primary and secondary constraints, first and second class constraints, restrictions on Lagrange multipliers, and both physical and gauge degrees of freedom. This relatively simple system provides a platform for discussing the Dirac conjecture, constructing Dirac brackets, and applying gauge conditions.

Topics & Concepts

PhysicsDirac (video compression format)Hamiltonian (control theory)Gauge theoryLagrange multiplierMathematical physicsTheoretical physicsHamiltonian systemGeneral relativityCanonical quantum gravityClassical mechanicsMathematicsQuantum mechanicsQuantum gravityQuantumLoop quantum gravityNeutrinoMathematical optimizationNoncommutative and Quantum Gravity TheoriesQuantum Mechanics and ApplicationsQuantum Mechanics and Non-Hermitian Physics
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