Retrieval of Three-Dimensional Raindrop Size Distribution Using X-Band Polarimetric Radar Data

Kim, Do Sang; Maki, Masayuki; Lee, D. I.

doi:10.1175/2010jtecha1407.1

Cited by 41 publications

(58 citation statements)

References 50 publications

(64 reference statements)

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“…The signal attenuation error is a common problem associated with the use of weather radar for QPE (Ryzhkov and Zrnic, 1995;Carey et al, 2000;Anagnostou et al, 2004;Matrosov et al, 2005;Park et al 2005;Maki et al 2005;Germann et al, 2006;Kim et al, 2010). Different algorithms have been developed to eliminate the attenuation error for different radar bands in in various environments (Carey et al, 2000;Matrosov et al, 2005;Park et al, 2005;Kim et al, 2010).…”

Section: The Challenge Of Radar-based Quantitative Precipitation Estimentioning

confidence: 99%

“…Different algorithms have been developed to eliminate the attenuation error for different radar bands in in various environments (Carey et al, 2000;Matrosov et al, 2005;Park et al, 2005;Kim et al, 2010). A significant disadvantage of X-band wavelengths is the signal extinction area.…”

Section: The Challenge Of Radar-based Quantitative Precipitation Estimentioning

confidence: 99%

“…This signal extinction problem can be solved by using data from entire radar observation networks . Park et al (2005) and Kim et al (2010) corrected for the attenuation effect in the Kanto region of Japan using X-band polarimetric weather data (MP-X Ebina).…”

Section: The Challenge Of Radar-based Quantitative Precipitation Estimentioning

confidence: 99%

See 2 more Smart Citations

Quantitative Precipitation Estimation and Hydrological Modeling in Japan

Shakti

2017

J. Japan Soc. Hydrol. and Water Resour.

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Section: The Challenge Of Radar-based Quantitative Precipitation Estimentioning

confidence: 99%

Section: The Challenge Of Radar-based Quantitative Precipitation Estimentioning

confidence: 99%

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Quantitative Precipitation Estimation and Hydrological Modeling in Japan

Shakti

2017

J. Japan Soc. Hydrol. and Water Resour.

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“…Kim et al (2010) developed a sophisticated method of attenuation correction for dual-polarimetric radar; however, the problem of attenuation effects has yet to be resolved for conventional radar using shorter wavelength (e.g., X-band). AITCC does not implement an attenuation correction scheme; however, conventional attenuation correction for convective precipitation (Doviak and Zrnić 1993) should be applied prior to running AITCC.…”

Section: Input Data For Aitccmentioning

confidence: 99%

Algorithm for the Identification and Tracking of Convective Cells Based on Constant and Adaptive Threshold Methods Using a New Cell-Merging and -Splitting Scheme

Shimizu

Uyeda

2012

Journal of the Meteorological Society of Japan

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“…These radars provide polarimetric parameters, including the horizontally polarized reflectivity factor (ZH), the vertically polarized reflectivity factor (ZV), differential reflectivity (ZDR), and the specific differential phase (KDP). Many QPE methods that use these parameters have been proposed (e.g., Jameson, 1991;Jameson and Caylor, 1994;5 Ryzhkov and Zrnić, 1995;Anagnostou et al, 2008;Kim et al, 2010;Ryzhkov et al, 2014;Adachi et al, 2015). Because QPE methods using dual polarimetric radar parameters is expected to be better than methods using single polarization radar data, we developed assimilation methods for dual polarimetric radar observations for both WRF Var and NHM-4DVAR.…”

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confidence: 99%

Observational operators for dual polarimetric radars in variational data assimilation systems

Kawabata

Schwitalla

Adachi

et al. 2018

Preprint

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Abstract. We developed two observational operators for dual polarimetric radars and implemented them in two variational data assimilation systems: WRF Var, the Weather Research and Forecasting Model variational data assimilation system, and 10 NHM-4DVAR, the nonhydrostatic variational data assimilation system for the Japan Meteorological Agency nonhydrostatic model. The operators consist of a space interpolator, two types of variable converters as well as their linearized and transposed (adjoint) operators. The space interpolator takes account of the effects of radar-beam broadening in both vertical and horizontal directions and climatological beam bending. The first variable converter emulates polarimetric parameters with model prognostic variables and includes attenuation effects, and the second one derives rainwater content from the observed 15 polarimetric parameter (specific differential phase). We developed linearized and adjoint operators for the space interpolator and variable converters and then assessed whether the linearity of the linearized operators and the accuracy of the adjoint operators were good enough for implementation in variational systems. The results of a simple assimilation experiment showed good agreement between assimilation results and observations with respect to reflectivity and specific differential phase but not with respect to differential reflectivity. 20

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Retrieval of Three-Dimensional Raindrop Size Distribution Using X-Band Polarimetric Radar Data

Cited by 41 publications

References 50 publications

Quantitative Precipitation Estimation and Hydrological Modeling in Japan

Quantitative Precipitation Estimation and Hydrological Modeling in Japan

Algorithm for the Identification and Tracking of Convective Cells Based on Constant and Adaptive Threshold Methods Using a New Cell-Merging and -Splitting Scheme

Observational operators for dual polarimetric radars in variational data assimilation systems

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