Quantum Network Tomography for General Topology with SPAM Errors

TL;DR

This paper introduces new methods for quantum network tomography that can identify internal channels in arbitrary topologies, even with realistic errors like SPAM, using simulations to validate their effectiveness.

Contribution

It presents Mergecast, a novel tomography method for arbitrary quantum network topologies, and extends it to handle SPAM errors with estimation protocols and simulations.

Findings

Mergecast enables unique identification of channels in arbitrary topologies.

The BypassUnicast method improves efficiency for bypassable Pauli channels.

Protocols remain effective under realistic noise conditions like photon loss.

Abstract

The goal of quantum network tomography (QNT) is the characterization of internal quantum channels in a quantum network from external peripheral operations. Prior research has primarily focused on star networks featuring bit-flip and depolarizing channels, leaving the broader problem -- such as QNT for networks with arbitrary topologies and general Pauli channels -- largely unexplored. Moreover, establishing channel identifiability remains a significant challenge even in simplified quantum star networks. In the first part of this paper, we introduce a novel network tomography method, termed Mergecast, in quantum networks. We demonstrate that Mergecast, together with a progressive etching procedure, enables the unique identification of all internal quantum channels in networks characterized by arbitrary topologies and Pauli channels. As a side contribution, we introduce a subclass of Pauli channels, termed bypassable Pauli channels, and propose a more efficient unicast-based tomography method, called BypassUnicast, for networks exclusively comprising these channels. In the second part, we extend our investigation to a more realistic QNT scenario that incorporates state preparation and measurement (SPAM) errors. We rigorously formulate SPAM errors in QNT, propose estimation protocols for such errors within QNT, and subsequently adapt our Mergecast approaches to handle networks affected by SPAM errors. Lastly, we conduct NetSquid-based simulations to corroborate the effectiveness of our proposed protocols in identifying internal quantum channels and estimating SPAM errors in quantum networks. In particular, we demonstrate that Mergecast maintains good performance under realistic conditions, such as photon loss and quantum memory decoherence.