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引用次数: 0
摘要
我们提出了一种基于积分技术(IBT)的算法来加速超新星(SN)辐射传递计算。该算法利用蒙特卡洛能量包的路径积分计算出的 "积分包",在三维时变辐射传递程序中合成在给定观测方向上观测到的能谱信号。与(Bulla et al.2015)提出的基于事件的技术(EBT)相比,我们的算法大大缩短了计算时间,提高了蒙特卡洛信噪比。利用一维球面对称 I 型超新星(SN Ia)喷出物模型 DDC10 及其衍生的三维模型,IBT 算法成功通过了以下验证:(1)球面对称性;(2)镜面对称性;(3)直接计数技术(DCT)和EBT在三维SN模型上的交叉比较。值得注意的是,在三维蒙特卡洛辐射传递代码 SEDONA 中实施我们的算法,在蒙特卡洛量子数相同的情况下,计算时间比 EBT 快 10-30 美元,信噪比(S/N)好 5-10 美元。
An Integral-Based Technique (IBT) to Accelerate the Monte-Carlo Radiative Transfer Computation for Supernovae
We present an integral-based technique (IBT) algorithm to accelerate
supernova (SN) radiative transfer calculations. The algorithm utilizes
``integral packets'', which are calculated by the path integral of the
Monte-Carlo energy packets, to synthesize the observed spectropolarimetric
signal at a given viewing direction in a 3-D time-dependent radiative transfer
program. Compared to the event-based technique (EBT) proposed by (Bulla et al.
2015), our algorithm significantly reduces the computation time and increases
the Monte-Carlo signal-to-noise ratio. Using a 1-D spherical symmetric type Ia
supernova (SN Ia) ejecta model DDC10 and its derived 3-D model, the IBT
algorithm has successfully passed the verification of: (1) spherical symmetry;
(2) mirror symmetry; (3) cross comparison on a 3-D SN model with
direct-counting technique (DCT) and EBT. Notably, with our algorithm
implemented in the 3-D Monte-Carlo radiative transfer code SEDONA, the
computation time is faster than EBT by a factor of $10-30$, and the
signal-to-noise (S/N) ratio is better by a factor of $5-10$, with the same
number of Monte-Carlo quanta.
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