Abstract
Abstract. The specific differential phase Kdp is one of the most important polarimetric radar variables, but the variance σ2(Kdp), regarding the errors in the calculation of the range derivative of the differential phase shift Φdp, is not well characterized due to the lack of a data generation model. This paper presents a probabilistic method based on the Gaussian mixture model for Kdp estimation at X-band frequency. The Gaussian mixture method can not only estimate the expected values of Kdp by differentiating the expected values of Φdp, but also obtain σ2(Kdp) from the product of the square of the first derivative of Kdp and the variance of Φdp. Additionally, the ambiguous phase and backscattering differential phase shift are corrected via the mixture model. The method is qualitatively evaluated with a convective event of a bow echo observed by the X-band dual-polarization radar in the University of Missouri. It is concluded that Kdp estimates are highly consistent with the gradients of Φdp in the leading edge of the bow echo, and large σ2(Kdp) occurs with high variation of Kdp. Furthermore, the performance is quantitatively assessed by 2-year radar–gauge data, and the results are compared to linear regression model. It is clear that Kdp-based rain amounts have good agreement with the rain gauge data, while the Gaussian mixture method gives improvements over the linear regression model, particularly for far ranges.
Highlights
Apart from radar reflectivity (ZH ) and differential reflectivity (ZDR), polarimetric radars obtain the differential phase shift to reflect the forward-scattering property of hydrometeor scatterers (Seliga and Bringi, 1978; Sachidananda and Zrnic, 1986)
A linear regression model has been developed to derive Kdp from the slope of the range profile of dp measured by the polarimetric radars
In order to quantitatively evaluate the accuracy of Gaussian mixture method (GMM) Kdp, hourly accumulated rain amounts are derived from the Xband rainfall rate algorithm (Chen and Chandrasekar, 2015) and compared to the rain gauge data collected at Bradford, Sanborn, Auxvasse, and Williamsburg between 1 April 2016 and 2 June 2018
Summary
Apart from radar reflectivity (ZH ) and differential reflectivity (ZDR), polarimetric radars obtain the differential phase shift ( dp) to reflect the forward-scattering property of hydrometeor scatterers (Seliga and Bringi, 1978; Sachidananda and Zrnic, 1986). The ambiguous dp is naturally corrected by examining the complex values of the range profiles of dp exponentials, and Kdp is estimated by a regularization framework based on a cubic spline smoothing (Wang and Chandrasekar, 2009) In this method, the bias and variance are adjustable through the smoothing parameter, giving high spatial resolutions of Kdp estimates. We propose a probabilistic method based on the Gaussian mixture model for Kdp estimation at X-band frequency. The Gaussian mixture method can estimate the expected values of Kdp by differentiating the conditional expectation of dp, and yield σ 2(Kdp) by regarding the errors in the calculation of the first derivative of dp.
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