QMC积分误差与拟渐近性

IF 0.8 Q3 STATISTICS & PROBABILITY

Monte Carlo Methods and Applications Pub Date : 2020-07-16 DOI:10.1515/mcma-2020-2067

I. Sobol, B. Shukhman

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引用次数: 1

摘要

摘要一种粗略的蒙特卡罗（MC）方法可以计算d维立方体上的积分。随着积分节点的数量N变大，MC方法的可能误差率随着O（1/N）{O（1/\sqrt{N}）}而降低。在MC算法中使用准随机点而不是随机点将其转换为准蒙特卡罗（QMC）方法。d维函数QMC积分的渐近误差估计包含乘法器1/N{1/N}。然而，乘数（ln⁡ N）d｛（\ln N）^｛d｝｝｝｝也是误差估计的一部分，这使得它实际上毫无用处。我们已经证明，在一般情况下，QMC误差估计不限于因子1/N{1/N}。然而，我们的数值实验表明，使用具有自然m的N=2m{N=2^{m}的Sobol序列的准随机点，使得积分误差近似与1/N{1/N}成比例。在我们的数值实验中，d≤15｛d\leq 15｝，并且我们使用了2011年发布的SOBOLSEQ16384代码生成的N≤2 40｛N\leq 2^｛40｝｝点。在该代码中，d≤2 14｛d\leq 2^｛14｝｝和N≤2 63｛N\leq 2 ^｛63｝｝｝。

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QMC integration errors and quasi-asymptotics

Abstract A crude Monte Carlo (MC) method allows to calculate integrals over a d-dimensional cube. As the number N of integration nodes becomes large, the rate of probable error of the MC method decreases as O ⁢ ( 1 / N ) {O(1/\sqrt{N})} . The use of quasi-random points instead of random points in the MC algorithm converts it to the quasi-Monte Carlo (QMC) method. The asymptotic error estimate of QMC integration of d-dimensional functions contains a multiplier 1 / N {1/N} . However, the multiplier ( ln ⁡ N ) d {(\ln N)^{d}} is also a part of the error estimate, which makes it virtually useless. We have proved that, in the general case, the QMC error estimate is not limited to the factor 1 / N {1/N} . However, our numerical experiments show that using quasi-random points of Sobol sequences with N = 2 m {N=2^{m}} with natural m makes the integration error approximately proportional to 1 / N {1/N} . In our numerical experiments, d ≤ 15 {d\leq 15} , and we used N ≤ 2 40 {N\leq 2^{40}} points generated by the SOBOLSEQ16384 code published in 2011. In this code, d ≤ 2 14 {d\leq 2^{14}} and N ≤ 2 63 {N\leq 2^{63}} .

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来源期刊

Monte Carlo Methods and Applications STATISTICS & PROBABILITY-

CiteScore

1.20

自引率

22.20%

发文量