轮廓动力学和轮廓手术:二维、无粘、不可压缩流动中扩展的高分辨率涡动力学模型的数值算法

David G. Dritschel
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引用次数: 310

摘要

传统上,实际上几乎完全是用欧拉数值方法,特别是谱方法来研究二维涡旋流中有规律发展的复杂流动情况。这些欧拉方法在模拟低到中等雷诺数流动方面做得非常好。然而,在典型的地球物理流的非常高的雷诺数下,欧拉方法遇到了困难,其中最重要的是足够的空间分辨率。另一方面,拉格朗日方法与轮廓动力学方法一样,具有固有的不粘性。因此,拉格朗日方法似乎非常适合于非常高雷诺数下的流动建模。然而,在实践中,拉格朗日方法本身受到无粘流的空间复杂性频繁、异常增加的限制。因此,拉格朗日方法被限制在相对简单的流动中,这些流动仍然是简单的。最近,轮廓动力学的扩展,“轮廓外科手术”,使复杂的无粘流动的建模完全拉格朗日术语,这种扩展克服了小规模结构的积累截断,在物理空间中,尺度的模拟范围。这种截断或“手术”的结果,是使流动的计算变得可行,其尺度范围跨越四到五个数量级,或比欧拉-拉格朗日方法所考虑的要大一到两个数量级。本文讨论了导致轮廓手术的轮廓动力学的历史,详细介绍了平面、圆柱、球面和准地转流的轮廓手术算法,介绍了高分辨率计算获得的新结果,包括首次将轮廓手术与传统的伪谱方法进行了比较,并概述了动力学/手术面临的一些突出问题。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Contour dynamics and contour surgery: Numerical algorithms for extended, high-resolution modelling of vortex dynamics in two-dimensional, inviscid, incompressible flows

The complex flow situations that regularly develop in a two-dimensional vortical flow h ave tradionally, indeed almost exclusively, been studied using Eulerian numerical methods, particularly spectral methods. These Eulerian methods have done remarkably well at modelling low to moderate Reynolds number flows.However, at the very high Reynolds numbers typical of geophysical flows, Eulerain methods run into difficulties, not the least of which is sufficient spatial resolutions. On the other hand, Lagrangian methods are and contour dynamics methods, are inherently inviscid. It would appear, therefore, that Lagrangian mehtods ideally suited for the modelling of flows at very high Reynolds numbers. Yet in practice, Lagrangian methods have themselves been limited by the frequent, extraordinary increase in the spatial complexity of inviscid flows. As a consequence, Lagrangian methods have been restricted to relatively simple flows which remain simple. Recently, an extension of contour dynamics, “contour surgery”, has enabled the modelling of complex inviscid flows in wholly Lagrangian terms, This extension overcomes the buildup of small-scale structure by truncating, in physical space, the modelled range of scales. The results of this truncation, or “surgery”, is to make feasible the computation of flows having a range of scales spanning four to five orders of magnitude, or one to two orders of magnitude greater than ever considered by Eulerian-Lagrangian methods. This paper discusses the history of contour dynamis which led to contour surgery, gives details of the contour surgery algorithm for planar, cylindrical, spherical, and quasi-geostrophic flow, presents new results obtained with high-resolutions calculations, including the first every comparison between contour surgery and a traditional pseudo- spectral method, and outlines some outstanding problems facing dynamics/ surgery.

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