Improved algorithms and coupled neutron-photon transport for auto-importance sampling method

The Auto-Importance Sampling(AIS) method is a Monte Carlo variance reduction technique proposed for deep penetration problems, which can significantly improve computational efficiency without pre-calculations for importance distribution. However, the AIS method is only validated with several simple...

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Bibliographic Details
Published in:Chinese physics C 2017, Vol.41 (1), p.100-109
Main Author: 王鑫 李君利 武祯 邱睿 李春艳 梁漫春 张辉 刚直 徐红
Format: Article
Language:English
Subjects:
中子
光子传输
完全耦合
抽样方法
改进算法
表面几何
计算效率
重要抽样法
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Summary:The Auto-Importance Sampling(AIS) method is a Monte Carlo variance reduction technique proposed for deep penetration problems, which can significantly improve computational efficiency without pre-calculations for importance distribution. However, the AIS method is only validated with several simple examples, and cannot be used for coupled neutron-photon transport. This paper presents improved algorithms for the AIS method, including particle transport, fictitious particle creation and adjustment, fictitious surface geometry, random number allocation and calculation of the estimated relative error. These improvements allow the AIS method to be applied to complicated deep penetration problems with complex geometry and multiple materials. A Completely coupled Neutron-Photon Auto-Importance Sampling(CNP-AIS) method is proposed to solve the deep penetration problems of coupled neutron-photon transport using the improved algorithms. The NUREG/CR-6115 PWR benchmark was calculated by using the methods of CNP-AIS, geometry splitting with Russian roulette and analog Monte Carlo, respectively. The calculation results of CNP-AIS are in good agreement with those of geometry splitting with Russian roulette and the benchmark solutions. The computational efficiency of CNP-AIS for both neutron and photon is much better than that of geometry splitting with Russian roulette in most cases, and increased by several orders of magnitude compared with that of the analog Monte Carlo.
ISSN:1674-1137
0254-3052
DOI:10.1088/1674-1137/41/1/014103