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arxiv 1903.01247 v1 pith:JJBC6JLS submitted 2019-03-04 physics.comp-ph hep-exhep-latphysics.data-an

Review of High-Quality Random Number Generators

classification physics.comp-ph hep-exhep-latphysics.data-an
keywords criteriahighestnumberqualitysystemscertaingeneratorsmeet
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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This is a review of pseudorandom number generators (RNG's) of the highest quality, suitable for use in the most demanding Monte Carlo calculations. All the RNG's we recommend here are based on the Kolmogorov-Anosov theory of mixing in classical mechanical systems, which guarantees under certain conditions and in certain asymptotic limits, that points on the trajectories of these systems can be used to produce random number sequences of exceptional quality. We outline this theory of mixing and establish criteria for deciding which RNG's are sufficiently good approximations to the ideal mathematical systems that guarantee highest quality. The well-known RANLUX (at highest luxury level) and its recent variant RANLUX++ are seen to meet our criteria, and some of the proposed versions of MIXMAX can be modified easily to meet the same criteria.

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