What is special about the Kirkwood-Dirac distributions? Only they produce natural conditional expectations

Abstract

Among the many quasiprobability representations of quantum mechanics, the family of Kirkwood-Dirac (KD) representations has come to the foreground in recent years. Each such KD representation is determined by the choice of two complementary complete sets of commuting observables A and B with respect to which it is Born-compatible, meaning that it correctly reproduces their Born probabilities for every state. We identify in this paper what property uniquely characterizes the KD representations among all such A and B Born-compatible quasiprobability representations. For that purpose, we first define a natural notion of quantum conditional expectation of an observable X, given an observable Y, in a state ρ, as a best estimator and we show that it has the basic properties generally expected of a conditional expectation. We then show that only the KD representations provide a notion of conditional expectation, given B (or given A) that coincides with the above quantum conditional expectation. As a byproduct of our analysis, we show a state-dependent no-go theorem. We prove that, if the quantum conditional expectation of an observable X, given an observable Y in a state ρ admits an anomalous value, then there cannot exist a Born-compatible joint probability distribution μ(x,y) for X and Y in the state ρ for which the associated conditional probability μ(x|y) yields a conditional expectation that coincides with the quantum conditional expectation. We further apply our findings to revisit a standard model for phase estimation in quantum metrology. We show in particular that, within the real sector of a given KD representation, the classical Fisher information of this phase estimation problem vanishes identically.