Quantum Algorithms for Community Detection and their Empirical Run-times

Cade, Chris; Folkertsma, Marten; Niesen, Ido; Weggemans, Jordi

doi:10.48550/arxiv.2203.06208

2022

DOI: 10.48550/arxiv.2203.06208

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Quantum Algorithms for Community Detection and their Empirical Run-times

Chris Cade¹,

Marten Folkertsma²,

Ido Niesen³

et al.

Abstract: We apply our recent work [9] on empirical estimates of quantum speedups to the practical task of community detection in complex networks. We design several quantum variants of a popular classical algorithm -the Louvain algorithm for community detection -and first study their complexities in the usual way, before analysing their complexities empirically across a variety of artificial and real inputs. We find that this analysis yields insights not available to us via the asymptotic analysis, further emphasising … Show more

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Cited by 1 publication

References 23 publications

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Quantifying Grover speed-ups beyond asymptotic analysis

Cade,

Folkertsma,

Niesen

et al. 2023

Quantum

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Run-times of quantum algorithms are often studied via an asymptotic, worst-case analysis. Whilst useful, such a comparison can often fall short: it is not uncommon for algorithms with a large worst-case run-time to end up performing well on instances of practical interest. To remedy this it is necessary to resort to run-time analyses of a more empirical nature, which for sufficiently small input sizes can be performed on a quantum device or a simulation thereof. For larger input sizes, alternative approaches are required.In this paper we consider an approach that combines classical emulation with detailed complexity bounds that include all constants. We simulate quantum algorithms by running classical versions of the sub-routines, whilst simultaneously collecting information about what the run-time of the quantum routine would have been if it were run instead. To do this accurately and efficiently for very large input sizes, we describe an estimation procedure and prove that it obtains upper bounds on the true expected complexity of the quantum algorithms.We apply our method to some simple quantum speedups of classical heuristic algorithms for solving the well-studied MAX-k-SAT optimization problem. This requires rigorous bounds (including all constants) on the expected- and worst-case complexities of two important quantum sub-routines: Grover search with an unknown number of marked items, and quantum maximum-finding. These improve upon existing results and might be of broader interest.Amongst other results, we found that the classical heuristic algorithms we studied did not offer significant quantum speedups despite the existence of a theoretical per-step speedup. This suggests that an empirical analysis such as the one we implement in this paper already yields insights beyond those that can be seen by an asymptotic analysis alone.

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Quantifying Grover speed-ups beyond asymptotic analysis

Cade,

Folkertsma,

Niesen

et al. 2023

Quantum

View full text Add to dashboard Cite

show abstract

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Quantum Algorithms for Community Detection and their Empirical Run-times

Cited by 1 publication

References 23 publications

Quantifying Grover speed-ups beyond asymptotic analysis

Quantifying Grover speed-ups beyond asymptotic analysis

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