Solving correlation clustering with QAOA and a Rydberg qudit system: a full-stack approach
Abstract
We study the correlation clustering problem using the quantum approximate optimization algorithm (QAOA) and qudits, which constitute a natural platform for such non-binary problems. Specifically, we consider a neutral atom quantum computer and propose a full stack approach for correlation clustering, including Hamiltonian formulation of the algorithm, analysis of its performance, identification of a suitable level structure for and specific gate design. We show the qudit implementation is superior to the qubit encoding as quantified by the gate count. For single layer QAOA, we also prove (conjecture) a lower bound of () for the approximation ratio on 3-regular graphs. Our numerical studies evaluate the algorithm's performance by considering complete and Erd\H{o}s-R\'enyi graphs of up to 7 vertices and clusters. We find that in all cases the QAOA surpasses the Swamy bound for the approximation ratio for QAOA depths . Finally, by analysing the effect of errors when solving complete graphs we find that their inclusion severely limits the algorithm's performance.
Cite
@article{arxiv.2106.11672,
title = {Solving correlation clustering with QAOA and a Rydberg qudit system: a full-stack approach},
author = {Jordi R. Weggemans and Alexander Urech and Alexander Rausch and Robert Spreeuw and Richard Boucherie and Florian Schreck and Kareljan Schoutens and Jiří Minář and Florian Speelman},
journal= {arXiv preprint arXiv:2106.11672},
year = {2022}
}
Comments
30+12 pages, 14 figures, accepted into Quantum