New methods for numerical evaluation of ultra-high degree and order associated Legendre functions

IF 0.5 4区 地球科学 Q4 GEOCHEMISTRY & GEOPHYSICS
Mehdi Goli, Ismael Foroughi, Pavel Novák
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引用次数: 0

Abstract

We improve the precision and computation speed of the fully-normalized associated Legendre functions (fnALFs) for ultra-high degrees and orders of spherical harmonic transforms. We take advantage of their numerical behaviour of and propose two new methods for solving an underflow/overflow problem in their calculation. We specifically discuss the application of the two methods in the fixed-order increasing-degree recursion computation technique. The first method uses successive ratios of fnALFs and the second method, called the Midway method, starts iteration from tiny initial values, which are still in the range of the IEEE double-precision environment, rather than from sectorial fnALFs. The underflow/overflow problem in the successive ratio method is handled by using a logarithm-based method and the extended range arithmetic. We validate both methods using numerical tests and compare their results with the X-number method in terms of precision, stability, and speed. The results show that the relative precision of the proposed methods is better than 10−9 for the maximum degree of 100000, compared to results derived by the high precision Wolfram’s Mathematica software. Average CPU times required for evaluation of fnALFs over different latitudes demonstrate that the two proposed methods are faster by about 10–30% and 20–90% with respect to the X-number method for the maximum degree in the range of 50–65000.

超高次阶相关勒让德函数数值计算的新方法
我们提高了超高次、超高阶球谐变换的全归一化相关勒让德函数(fnALFs)的精度和计算速度。我们利用它们的数值特性,在计算中提出了两种新的方法来解决下溢问题。具体讨论了这两种方法在定阶递增递归计算技术中的应用。第一种方法使用fnalf的连续比率,第二种方法称为中途方法,从仍然在IEEE双精度环境范围内的微小初始值开始迭代,而不是从扇形fnalf开始迭代。采用基于对数的方法和扩展极差算法处理连续比值法中的下溢问题。我们使用数值测试验证了这两种方法,并将其结果与x数方法在精度、稳定性和速度方面进行了比较。结果表明,与高精度的Wolfram 's Mathematica软件计算结果相比,在最大100000度下,所提方法的相对精度优于10−9。在不同纬度上评估fnALFs所需的平均CPU时间表明,在50-65000的最大程度范围内,两种方法相对于X-number方法的速度分别快约10-30%和20-90%。
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来源期刊
Studia Geophysica et Geodaetica
Studia Geophysica et Geodaetica 地学-地球化学与地球物理
CiteScore
1.90
自引率
0.00%
发文量
8
审稿时长
6-12 weeks
期刊介绍: Studia geophysica et geodaetica is an international journal covering all aspects of geophysics, meteorology and climatology, and of geodesy. Published by the Institute of Geophysics of the Academy of Sciences of the Czech Republic, it has a long tradition, being published quarterly since 1956. Studia publishes theoretical and methodological contributions, which are of interest for academia as well as industry. The journal offers fast publication of contributions in regular as well as topical issues.
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