从非常稀疏的拉格朗日数据中识别主要流量特征:一种基于多尺度递归网络的方法

IF 2.3 3区 工程技术 Q2 ENGINEERING, MECHANICAL Experiments in Fluids Pub Date : 2023-09-21 DOI:10.1007/s00348-023-03700-0
Giovanni Iacobello, David E. Rival
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引用次数: 2

摘要

现实的流体流动问题通常要求拉格朗日示踪剂以稀疏或非常稀疏的方式部署,例如对于需要表征大规模运动的海洋和大气流动。数据稀疏性是拉格朗日分析中的一个重要问题,尤其是对于严重依赖大型数据集的数据驱动方法。我们提出了一种多尺度空间递归网络(MSRN)方法来表征非常稀疏的拉格朗日数据,该方法利用单个轨迹和空间递归标准来识别示踪剂轨迹的时空复杂性。MSRN是一个无监督的建模框架,不需要先验参数设置,通过量化特定轨迹间隔下的持续链接激活,可以揭示各种显著流体流中存在的主导循环尺度。这一新范式被证明是成功的,用于研究复杂(现实)流中的拉格朗日示踪剂,包括非定常和平流主导的问题。这使得MSRN成为一种有效且通用的工具,可以在关键问题中表征传感器轨迹,例如对理解和缓解气候变化至关重要的环境过程。
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Identifying dominant flow features from very-sparse Lagrangian data: a multiscale recurrence network-based approach

Realistic fluid flow problems often require that Lagrangian tracers are deployed in a sparse or very-sparse manner, such as for oceanic and atmospheric flows where large-scale motion needs characterisation. Data sparsity represents a significant issue in Lagrangian analysis, especially for data-driven methods that rely heavily on large datasets. We propose a multiscale spatial recurrence network (MSRN) methodology for characterising very-sparse Lagrangian data, which exploits individual tracks and a spatial recurrence criterion to identify the spatio-temporal complexity of tracer trajectories. The MSRN is an unsupervised modelling framework that does not require a priori parameter setting, and—through the quantification of persistent link activation at specific trajectory intervals—can reveal the presence of dominant looping scales in a variety of salient fluid flows. This new paradigm is shown to be successful for the study of Lagrangian tracers seeded in complex (realistic) flows, including unsteady and advection-dominated problems. This makes MSRNs an effective and versatile tool to characterise sensor trajectories in key problems such as environmental processes critical to understanding and mitigating climate change.

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来源期刊
Experiments in Fluids
Experiments in Fluids 工程技术-工程:机械
CiteScore
5.10
自引率
12.50%
发文量
157
审稿时长
3.8 months
期刊介绍: Experiments in Fluids examines the advancement, extension, and improvement of new techniques of flow measurement. The journal also publishes contributions that employ existing experimental techniques to gain an understanding of the underlying flow physics in the areas of turbulence, aerodynamics, hydrodynamics, convective heat transfer, combustion, turbomachinery, multi-phase flows, and chemical, biological and geological flows. In addition, readers will find papers that report on investigations combining experimental and analytical/numerical approaches.
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