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A faster hafnian formula for complex matrices and its benchmarking on a supercomputer

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arxiv 1805.12498 v3 pith:V4YY6MET submitted 2018-05-31 cs.DS quant-ph

A faster hafnian formula for complex matrices and its benchmarking on a supercomputer

classification cs.DS quant-ph
keywords hafniancomplexmatricestimesalgorithmscomputesupercomputeralgorithm
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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We introduce new and simple algorithms for the calculation of the number of perfect matchings of complex weighted, undirected graphs with and without loops. Our compact formulas for the hafnian and loop hafnian of $n \times n $ complex matrices run in $O(n^3 2^{n/2})$ time, are embarrassingly parallelizable and, to the best of our knowledge, are the fastest exact algorithms to compute these quantities. Despite our highly optimized algorithm, numerical benchmarks on the Titan supercomputer with matrices up to size $56 \times 56$ indicate that one would require the 288000 CPUs of this machine for about a month and a half to compute the hafnian of a $100 \times 100$ matrix.

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