Accuracy matrix in generalized simultaneous measurement of a qubit system

TL;DR

This paper introduces an accuracy matrix for qubit measurements, deriving new trade-off relations that quantify measurement errors, complementarity, and back-action, with applications to quantum state tomography and estimation.

Contribution

It formulates a 3x3 accuracy matrix for qubit measurements, establishing novel trade-off relations and linking measurement accuracy to estimation theory.

Findings

Derived trade-off relations between measurement accuracies of noncommuting observables.

Connected the accuracy matrix to Fisher information and maximum-likelihood estimation.

Applied the framework to analyze quantum state tomography and measurement errors.

Abstract

We formulate the accuracy of quantum measurement for a qubit system in terms of a 3 by 3 matrix. This matrix, which we refer to as the accuracy matrix, can be calculated from a positive operator-valued measure (POVM) corresponding to the quantum measurement. Based on the accuracy matrix, we derive new trade-off relations between the measurement accuracy of two or three noncommuting observables of a qubit system. These trade-off relations offer a quantitative information-theoretic representation of Bohr's principle of complementarity. They can be interpreted as the uncertainty relations between measurement errors in simultaneous measurements, and also as the trade-off relations between the measurement error and back-action of measurement. A no-cloning inequality is derived from the trade-off relations. Furthermore, our formulation and the obtained results can be applied to analyze quantum state tomography. We also show that the accuracy matrix is closely related to the maximum-likelihood estimation and the Fisher information matrix for a finite number of samples; the accuracy matrix tells us how accurately we can estimate the probability distributions of observables of an unknown state by quantum measurement.