结合降雨微物理模式和观测:对雷达降雨估计的影响

2009 IEEE Radar Conference Pub Date : 2009-05-04 DOI:10.1109/RADAR.2009.4977122

O. Prat, A. Barros

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引用次数: 5

摘要

在雷达降水估计中，采用bin模型对动态微物理过程的Z-R关系特征进行了表征。所进行的敏感性分析表明，在低至中等雨强(R≪20mm h - 1)地区，聚结是主要的微物理过程，该地区的降雨率在很大程度上取决于DSD的光谱特性(即形状)。对于高强度降雨(R > 20mm h−1)，碰撞-破碎动力学主导了雨滴光谱的演化。对模型产生的随时间变化的Z-R关系的分析表明，强降雨的Z-R关系趋同于普遍的Z-R关系。相反，模式结果表明，Z-R关系严重低估了小雨条件下的反射率。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Combining a rain microphysical model and observations: Implications for radar rainfall estimation

A bin-model was used to characterize the signature of dynamical microphysical processes on Z-R relationships used for radar rainfall estimation. The sensitivity analysis performed shows that coalescence is the dominant microphysical process for low to moderate rain intensity regimes (R ≪ 20mm h−1), and that rain rate in this regime is strongly dependent on the spectral properties of the DSD (i.e. the shape). For high intensity rainfall (R ≫ 20mm h−1), collision-breakup dynamics dominate the evolution of the raindrop spectra. Analysis of the time-dependent Z-R relationships produced by the model suggests convergence to a universal Z-R relationship for heavy intensity rainfall. Conversely, the model results show that Z-R relationships severely underestimate reflectivity in the light rainfall regime.

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2009 IEEE Radar Conference

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