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Main Authors: Campbell, Conall J., Mackinnon, Matthew, Paternostro, Mauro, Chisholm, Diana A.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2506.11289
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author Campbell, Conall J.
Mackinnon, Matthew
Paternostro, Mauro
Chisholm, Diana A.
author_facet Campbell, Conall J.
Mackinnon, Matthew
Paternostro, Mauro
Chisholm, Diana A.
contents The characterisation of quantum networks is fundamental to understanding how energy and information propagates through complex systems, with applications in control, communication, error mitigation and energy transfer. In this work, we explore the use of external probes to infer the network topology in the context of continuous-time quantum walks, where a single excitation traverses the network with a pattern strongly influenced by its topology. The probes act as decay channels for the excitation, and can be interpreted as performing an indirect measurement on the network dynamics. By making use of a Genetic Optimisation algorithm, we demonstrate that the data collected by the probes can be used to successfully reconstruct the topology of any quantum network with high success rates, where performance is limited only by computational resources for large network sizes. Moreover, we show that increasing the number of probes significantly simplifies the reconstruction task, revealing a tradeoff between the number of probes and the required computational power.
format Preprint
id arxiv_https___arxiv_org_abs_2506_11289
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Inferring Quantum Network Topologies using Genetic Optimisation of Indirect Measurements
Campbell, Conall J.
Mackinnon, Matthew
Paternostro, Mauro
Chisholm, Diana A.
Quantum Physics
The characterisation of quantum networks is fundamental to understanding how energy and information propagates through complex systems, with applications in control, communication, error mitigation and energy transfer. In this work, we explore the use of external probes to infer the network topology in the context of continuous-time quantum walks, where a single excitation traverses the network with a pattern strongly influenced by its topology. The probes act as decay channels for the excitation, and can be interpreted as performing an indirect measurement on the network dynamics. By making use of a Genetic Optimisation algorithm, we demonstrate that the data collected by the probes can be used to successfully reconstruct the topology of any quantum network with high success rates, where performance is limited only by computational resources for large network sizes. Moreover, we show that increasing the number of probes significantly simplifies the reconstruction task, revealing a tradeoff between the number of probes and the required computational power.
title Inferring Quantum Network Topologies using Genetic Optimisation of Indirect Measurements
topic Quantum Physics
url https://arxiv.org/abs/2506.11289