State-independent Uncertainty Relations and Entanglement Detection

TL;DR

This paper introduces a method to derive state-independent uncertainty relations in quantum mechanics, applicable to pure and mixed states, and uses these relations to develop practical entanglement detection criteria.

Contribution

The authors develop a novel approach to obtain state-independent uncertainty bounds using eigenvalues of Hermitian matrices formed from Bloch vectors, applicable to multiple observables.

Findings

Derived uncertainty relations with universal lower bounds.

Applicable to both pure and mixed quantum states.

Provided practical criteria for entanglement detection.

Abstract

The uncertainty relation is one of the key ingredients of quantum theory. Despite the great efforts devoted to this subject, most of the variance-based uncertainty relations are state-dependent and suffering from the triviality problem of zero lower bounds. Here we develop a method to get uncertainty relations with state-independent lower bounds. The method works by exploring the eigenvalues of a Hermitian matrix composed by Bloch vectors of incompatible observables and is applicable for both pure and mixed states and for arbitrary number of N- dimensional observables. The uncertainty relation for incompatible observables can be explained by geometric relations related to the parallel postulate and the inequalities in Horn's conjecture on Hermitian matrix sum. Practical entanglement criteria are also presented based on the derived uncertainty relations.