Three-Dimensional Variational Multi-Doppler Wind Retrieval over complex terrain

IF 1.9 4区 地球科学 Q2 ENGINEERING, OCEAN
Ting-Yu Cha, M. Bell
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引用次数: 0

Abstract

The interaction of airflow with complex terrain has the potential to significantly amplify extreme precipitation events and modify the structure and intensity of precipitating cloud systems. However, understanding and forecasting such events is challenging, in part due to the scarcity of direct in-situ measurements. Doppler radar can provide the capability to monitor extreme rainfall events over land, but our understanding of airflow modulated by orographic interactions remains limited. The SAMURAI software is a three-dimensional variational (3DVAR) technique that uses the finite element approach to retrieve kinematic and thermodynamic fields. The analysis has high fidelity to observations when retrieving flows over a flat surface, but the capability of imposing topography as a boundary constraint is not previously implemented. Here we implement the immersed boundary method (IBM) as pseudo-observations at their native coordinates in SAMURAI to represent the topographic forcing and surface impermeability. In this technique, neither data interpolation onto a Cartesian grid nor explicit physical constraint integration during the cost function minimization is needed. Furthermore, the physical constraints are treated as pseudo-observations, offering the flexibility to adjust the strength of the boundary condition. A series of observing simulation sensitivity experiments (OSSEs) using a full-physics model and radar emulator simulating rainfall from Typhoon Chanthu (2021) over Taiwan are conducted to evaluate the retrieval accuracy and parameter settings. The OSSE results show that the strength of the IBM constraints can impact the overall wind retrievals. Analysis from real radar observations further demonstrates that the improved retrieval technique can advance scientific analyses for the underlying dynamics of orographic precipitation using radar observations.
复杂地形上三维变分多普勒风反演
气流与复杂地形的相互作用有可能显著放大极端降水事件,改变降水云系统的结构和强度。然而,理解和预测此类事件具有挑战性,部分原因是缺乏直接的原位测量。多普勒雷达可以提供监测陆地上极端降雨事件的能力,但我们对地形相互作用调制的气流的理解仍然有限。SAMURAI软件是一种三维变分(3DVAR)技术,它使用有限元方法来检索运动学和热力学场。当在平坦表面上检索流动时,该分析对观测结果具有很高的保真度,但以前没有实现将地形作为边界约束的能力。在SAMURAI中,我们将浸入边界法(IBM)作为在其本地坐标上的伪观测值来表示地形强迫和表面不渗透性。在该技术中,既不需要将数据插值到笛卡尔网格上,也不需要在成本函数最小化过程中进行显式的物理约束积分。此外,物理约束被视为伪观测,提供了调整边界条件强度的灵活性。利用全物理模型和雷达模拟器模拟台风“灿都”(2021)在台湾的降雨,进行了一系列观测模拟灵敏度实验(OSSEs),以评估反演精度和参数设置。OSSE结果表明,IBM约束的强度会影响总体风检索。实际雷达观测资料的分析进一步表明,改进后的反演技术可以促进利用雷达观测资料对地形降水潜在动力学的科学分析。
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来源期刊
CiteScore
4.50
自引率
9.10%
发文量
135
审稿时长
3 months
期刊介绍: The Journal of Atmospheric and Oceanic Technology (JTECH) publishes research describing instrumentation and methods used in atmospheric and oceanic research, including remote sensing instruments; measurements, validation, and data analysis techniques from satellites, aircraft, balloons, and surface-based platforms; in situ instruments, measurements, and methods for data acquisition, analysis, and interpretation and assimilation in numerical models; and information systems and algorithms.
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