Resource-efficient simulation of noisy quantum circuits and application to network-enabled QRAM optimization
Abstract
Giovannetti, Lloyd, and Maccone [Phys. Rev. Lett. 100, 160501] proposed a quantum random access memory (QRAM) architecture to retrieve arbitrary superpositions of (quantum) memory cells via quantum switches and address qubits. Towards physical QRAM implementations, Chen et al. [PRX Quantum 2, 030319] recently showed that QRAM maps natively onto optically connected quantum networks with overhead and built-in error detection. However, modeling QRAM on large networks has been stymied by exponentially rising classical compute requirements. Here, we address this bottleneck by: (i) introducing a resource-efficient method for simulating large-scale noisy entanglement, allowing us to evaluate hundreds and even thousands of qubits under various noise channels; and (ii) analyzing Chen et al.'s network-based QRAM as an application at the scale of quantum data centers or near-term quantum internet; and (iii) introducing a modified network-based QRAM architecture to improve quantum fidelity and access rate. We conclude that network-based QRAM could be built with existing or near-term technologies leveraging photonic integrated circuits and atomic or atom-like quantum memories.
Cite
@article{arxiv.2210.13494,
title = {Resource-efficient simulation of noisy quantum circuits and application to network-enabled QRAM optimization},
author = {Luís Bugalho and Emmanuel Zambrini Cruzeiro and Kevin C. Chen and Wenhan Dai and Dirk Englund and Yasser Omar},
journal= {arXiv preprint arXiv:2210.13494},
year = {2023}
}
Comments
Keywords: Quantum RAM, Distributed Quantum Computation, Photonic Quantum Networks; Revised version with new section discussing the validity of the results