Minimization of the estimation error for entanglement distribution networks with arbitrary noise

TL;DR

This paper introduces a local measurement protocol for estimating the average fidelity of entangled qubit pairs in noisy quantum networks, achieving minimal mean squared error without prior noise knowledge.

Contribution

It presents a novel, implementation-friendly fidelity estimation protocol that minimizes estimation error under arbitrary noise conditions, outperforming existing methods.

Findings

Reduces estimation error in i.i.d. noise scenarios

Effective under correlated noise conditions

Uses only local Pauli measurements

Abstract

Fidelity estimation is essential for the quality control of entanglement distribution networks. Because measurements collapse quantum states, we consider a setup in which nodes randomly sample a subset of the entangled qubit pairs to measure and then estimate the average fidelity of the unsampled pairs conditioned on the measurement outcome. The proposed estimation protocol achieves the lowest mean squared estimation error in a difficult scenario with arbitrary noise and no prior information. Moreover, this protocol is implementation friendly because it only performs local Pauli operators according to a predefined sequence. Numerical studies show that compared to existing fidelity estimation protocols, the proposed protocol reduces the estimation error in both scenarios with i.i.d. noise and correlated noise.