{"title":"单调无约束方案转换器 (MUST):使用有限体积法消除无约束方案族中的下冲和过冲的方法","authors":"Y.F. Yap, J.C. Chai","doi":"10.1108/hff-04-2024-0293","DOIUrl":null,"url":null,"abstract":"<h3>Purpose</h3>\n<p>This paper presents a Monotonic Unbounded Schemes Transformer (MUST) approach to bound/monotonize (remove undershoots and overshoots) unbounded spatial differencing schemes automatically, and naturally. Automatically means the approach (1) captures the critical cell Peclet number when an unbounded scheme starts to produce physically unrealistic solution automatically, and (2) removes the undershoots and overshoots as part of the formulation without requiring human interventions. Naturally implies, all the terms in the discretization equation of the unbounded spatial differencing scheme are retained.</p><!--/ Abstract__block -->\n<h3>Design/methodology/approach</h3>\n<p>The authors do not formulate new higher-order scheme. 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引用次数: 0
摘要
本文提出了一种单调无约束方案转换器(MUST)方法,用于自动、自然地约束/单调化(消除下冲和过冲)无约束空间差分方案。自动是指该方法:(1)当无约束方案开始自动产生物理上不现实的解时,捕捉临界单元佩克莱特数;(2)作为公式的一部分,无需人工干预即可消除下冲和过冲。设计/方法/途径 作者没有制定新的高阶方案。结果当单元佩克莱特数小于临界单元佩克莱特数时,使用 MUST 得到的解与不使用 MUST 得到的解完全相同。当单元佩克莱特数大于临界单元佩克莱特数时,MUST 会将节点值设置为针对当前问题可推导出的极限值。作者提出了一种推导极限值的方法。作者在中心差分方案、二阶上风差分方案和 QUICK 差分方案上对 MUST 进行了测试。在测试的所有情况下,MUST 都能 (1) 捕获临界单元佩克莱特数;发生过冲和下冲时的确切位置,以及 (2) 将节点值限制在限制器值的范围内。这些都是通过自然保留各自差分方案的所有离散项来实现的,并在离散化过程中自动完成。作者使用一维问题演示了 MUST。附录中显示了二维对流扩散问题的结果,以说明 MUST 的通用性。原创性/价值作者提出了一种原创方法,可将任何无界方案转换为有界方案,同时保留原始离散方程中的所有项。
Monotonic unbounded schemes transformer (MUST): an approach to remove undershoots and overshoots in family of unbounded schemes using finite-volume method
Purpose
This paper presents a Monotonic Unbounded Schemes Transformer (MUST) approach to bound/monotonize (remove undershoots and overshoots) unbounded spatial differencing schemes automatically, and naturally. Automatically means the approach (1) captures the critical cell Peclet number when an unbounded scheme starts to produce physically unrealistic solution automatically, and (2) removes the undershoots and overshoots as part of the formulation without requiring human interventions. Naturally implies, all the terms in the discretization equation of the unbounded spatial differencing scheme are retained.
Design/methodology/approach
The authors do not formulate new higher-order scheme. MUST transforms an unbounded higher-order scheme into a bounded higher-order scheme.
Findings
The solutions obtained with MUST are identical to those without MUST when the cell Peclet number is smaller than the critical cell Peclet number. For cell Peclet numbers larger than the critical cell Peclet numbers, MUST sets the nodal values to the limiter value which can be derived for the problem at-hand. The authors propose a way to derive the limiter value. The authors tested MUST on the central differencing scheme, the second-order upwind differencing scheme and the QUICK differencing scheme. In all cases tested, MUST is able to (1) capture the critical cell Peclet numbers; the exact locations when overshoots and undershoots occur, and (2) limit the nodal value to the value of the limiter values. These are achieved by retaining all the discretization terms of the respective differencing schemes naturally and accomplished automatically as part of the discretization process. The authors demonstrated MUST using one-dimensional problems. Results for a two-dimensional convection–diffusion problem are shown in Appendix to show generality of MUST.
Originality/value
The authors present an original approach to convert any unbounded scheme to bounded scheme while retaining all the terms in the original discretization equation.
期刊介绍:
The main objective of this international journal is to provide applied mathematicians, engineers and scientists engaged in computer-aided design and research in computational heat transfer and fluid dynamics, whether in academic institutions of industry, with timely and accessible information on the development, refinement and application of computer-based numerical techniques for solving problems in heat and fluid flow. - See more at: http://emeraldgrouppublishing.com/products/journals/journals.htm?id=hff#sthash.Kf80GRt8.dpuf
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