Fidelity-based distance bounds for $N$-qubit approximate quantum error correction
Abstract
The Eastin-Knill theorem is a central result of quantum error correction theory and states that a quantum code cannot correct errors exactly, possess continuous symmetries, and implement a universal set of gates transversely. As a way to circumvent this result, there are several approaches in which one gives up on either exact error correction or continuous symmetries. In this context, it is common to employ a complementary measure of fidelity as a way to quantify quantum state distinguishability and benchmark approximations in error correction. Despite having useful properties, evaluating fidelity measures stands as a challenging task for quantum states with a large number of entangled qubits. With that in mind, we address two distance measures based on the sub- and superfidelities as a way to bound error approximations, which in turn require a lower computational cost. We model the lack of exact error correction to be equivalent to the action of a single dephasing channel, evaluate the proposed fidelity-based distances both analytically and numerically, and obtain a closed-form expression for a general -qubit quantum state. We illustrate our bounds with two paradigmatic examples, an -qubit mixed GHZ state and an -qubit mixed state.
Cite
@article{arxiv.2212.04368,
title = {Fidelity-based distance bounds for $N$-qubit approximate quantum error correction},
author = {Guilherme Fiusa and Diogo O. Soares-Pinto and Diego Paiva Pires},
journal= {arXiv preprint arXiv:2212.04368},
year = {2023}
}
Comments
12 pages, 6 figures. Close to published version