English

Distributing circuits over heterogeneous, modular quantum computing network architectures

Quantum Physics 2025-05-22 v3

Abstract

We consider a heterogeneous network of quantum computing modules, sparsely connected via Bell states. Operations across these connections constitute a computational bottleneck and they are likely to add more noise to the computation than operations performed within a module. We introduce several techniques for transforming a given quantum circuit into one implementable on a network of the aforementioned type, minimising the number of Bell states required to do so. We extend previous works on circuit distribution over fully connected networks to the case of heterogeneous networks. On the one hand, we extend the hypergraph approach of [Andres-Martinez & Heunen. 2019] to arbitrary network topologies. We additionally make use of Steiner trees to find efficient realisations of the entanglement sharing within the network, reusing already established connections as often as possible. On the other hand, we extend the embedding techniques of [Wu, et al. 2022] to networks with more than two modules. Furthermore, we discuss how these two seemingly incompatible approaches can be made to cooperate. Our proposal is implemented and benchmarked; the results confirming that, when orchestrated, the two approaches complement each other's weaknesses.

Keywords

Cite

@article{arxiv.2305.14148,
  title  = {Distributing circuits over heterogeneous, modular quantum computing network architectures},
  author = {Pablo Andres-Martinez and Tim Forrer and Daniel Mills and Jun-Yi Wu and Luciana Henaut and Kentaro Yamamoto and Mio Murao and Ross Duncan},
  journal= {arXiv preprint arXiv:2305.14148},
  year   = {2025}
}

Comments

30 pages, 18 figures, comments welcome; v2 - Add link to experiment data; v3 - 31 pages, small updates to discussion and references

R2 v1 2026-06-28T10:43:07.738Z