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A benchmarking study of quantum algorithms for combinatorial optimization

K. Sankar, A. Scherer, S. Kako, S. Reifenstein, Navid Ghadermarzy, Willem B. Krayenhoff, Y. Inui, Edwin Ng, Tatsuhiro Onodera, Pooya Ronagh, Y. Yamamoto·May 7, 2021·DOI: 10.1038/s41534-024-00856-3
Physics

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Abstract

We study the performance scaling of three quantum algorithms for combinatorial optimization: measurement-feedback coherent Ising machines (MFB-CIM), discrete adiabatic quantum computation (DAQC), and the Dürr–Høyer algorithm for quantum minimum finding (DH-QMF) that is based on Grover’s search. We use M ax C ut problems as a reference for comparison, and time-to-solution (TTS) as a practical measure of performance for these optimization algorithms. For each algorithm, we analyze its performance in solving two types of M ax C ut problems: weighted graph instances with randomly generated edge weights attaining 21 equidistant values from −1 to 1; and randomly generated Sherrington–Kirkpatrick (SK) spin glass instances. We empirically find a significant performance advantage for the studied MFB-CIM in comparison to the other two algorithms. We empirically observe a sub-exponential scaling for the median TTS for the MFB-CIM, in comparison to the almost exponential scaling for DAQC and the proven $$\widetilde{{{{\mathcal{O}}}}}\left(\sqrt{{2}^{n}}\right)$$ O ̃ 2 n scaling for DH-QMF. We conclude that the MFB-CIM outperforms DAQC and DH-QMF in solving M ax C ut problems.

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