A note on complete gauge-fixing and the constraint algebra

Abstract

The admissibility of a gauge-fixing is governed by the invertibility of =\σa,γb\ where σa are gauge-fixing conditions and γb are independent first-class constraints. We prove, via the Schur complement, that the determinant of the combined constraint matrix M=\A, B\ built from all constraints and gauge-fixing conditions factorises as ≈()2 C, where C is the second-class constraint matrix, providing an alternative criterion for admissibility. Since C≠0 by definition, the second-class sector decouples entirely from the gauge-fixing sector. In the algebraic case, this factorisation identifies the Hamiltonian admissibility criterion of Henneaux and Teitelboim with the Lagrangian completeness criterion of Motohashi, Suyama, and Takahashi. We identify a metric ansatz as gauge-fixing at the action level and analyse completeness in the context of spherically symmetric spacetime. The factorisation ensures that completeness is robust to the second-class sector that arises in modified theories of gravity.