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**Geoscientific Model Development**
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**Model description paper**
13 Sep 2019

**Model description paper** | 13 Sep 2019

A radar reflectivity operator with ice-phase hydrometeors for variational data assimilation (version 1.0) and its evaluation with real radar data

^{1}Collaborative Innovation Center on Forecast and Evaluation of Meteorological Disasters, Key Laboratory of Meteorological Disaster of Ministry of Education, Nanjing University of Information Science and Technology, Nanjing, 210044, China^{2}National Center for Atmospheric Research, Boulder, CO 80301, USA

^{1}Collaborative Innovation Center on Forecast and Evaluation of Meteorological Disasters, Key Laboratory of Meteorological Disaster of Ministry of Education, Nanjing University of Information Science and Technology, Nanjing, 210044, China^{2}National Center for Atmospheric Research, Boulder, CO 80301, USA

**Correspondence**: Zhiquan Liu (liuz@ucar.edu)

**Correspondence**: Zhiquan Liu (liuz@ucar.edu)

Abstract

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A reflectivity forward operator and its associated tangent linear and adjoint operators (together named RadarVar) were developed for variational data assimilation (DA). RadarVar can analyze both rainwater and ice-phase species (snow and graupel) by directly assimilating radar reflectivity observations. The results of three-dimensional variational (3D-Var) DA experiments with a 3 km grid mesh setting of the Weather Research and Forecasting (WRF) model showed that RadarVar was effective at producing an analysis of reflectivity pattern and intensity similar to the observed data. Two to three outer loops with 50–100 iterations in each loop were needed to obtain a converged 3-D analysis of reflectivity, rainwater, snow, and graupel, including the melting layers with mixed-phase hydrometeors. It is shown that the deficiencies in the analysis using this operator, caused by the poor quality of the background fields and the use of the static background error covariance, can be partially resolved by using radar-retrieved hydrometeors in a preprocessing step and tuning the spatial correlation length scales of the background errors. The direct radar reflectivity assimilation using RadarVar also improved the short-term (2–5 h) precipitation forecasts compared to those of the experiment without DA.

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Wang, S. and Liu, Z.: A radar reflectivity operator with ice-phase hydrometeors for variational data assimilation (version 1.0) and its evaluation with real radar data, Geosci. Model Dev., 12, 4031–4051, https://doi.org/10.5194/gmd-12-4031-2019, 2019.

1 Introduction

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Over the past several decades, radar reflectivity observations have been
used in many data assimilation (DA) studies (Borderies et al., 2018; Caumont
et al., 2010; Gao and Stensrud, 2012; Hu et al., 2006; Jung et al., 2010, 2008a; Liu et al., 2019; Putnam et al., 2014; Snook et al.,
2012, 2015; Sun and Crook, 1997; Sun and Wang, 2013; Tong and Xue, 2005;
Wang et al., 2013b; Wang and Wang, 2017; Wattrelot et al., 2014; Xiao et
al., 2007; Xue et al., 2006) and they have demonstrated that assimilating
this radar reflectivity improves the initial conditions of the convective
scale and benefits the subsequent forecasts. To assimilate the reflectivity,
it is necessary to transform the model's prognostic variables (e.g.,
rainwater, snow, and graupel) to the observed radar reflectivity. To perform
this transformation, early studies (e.g., Sun and Crook, 1997; Xiao et al.,
2007) used the Marshall–Palmer distribution of raindrop size (*Z*–*R*
relationship). However, this relationship is only valid in precipitation
areas without ice-phase species; thus, its applications (e.g., Schwitalla
and Wulfmeyer, 2018) are often limited to layers lower than 4 km or 8 km
above ground level (a.g.l.). To overcome this deficiency, more comprehensive
operators that involve snow and graupel have been developed (Gao and
Stensrud, 2012; Tong and Xue, 2005). Several studies (e.g., Gao and
Stensrud, 2012; Wang and Wang, 2017) have demonstrated that involving these
ice species in the reflectivity operator improves the analysis of
hydrometeors in terms of their spatial distribution, especially in the
vertical direction.

Although these operators have been successfully applied in many convective-scale DA studies, they were developed for a specific band of radar (e.g., S-band radar; Gao and Stensrud, 2012; Sun and Crook, 1997) and specific microphysics characteristics (e.g., with a fixed intercept parameter; Sun and Crook, 1997). However, mixed-phase species such as wet snow and wet graupel have not been considered in these operators. Recently, the contributions from mixed-phase species have been studied (Jung et al., 2008a, hereafter, J08; Posselt et al., 2015). To compute the mixed-phase species' contributions, J08 proposed an operator that was based on the expressions given by Zhang et al. (2001). Their expressions were derived according to the scattering amplitudes that were estimated through the T-matrix method and the Rayleigh scattering approximation (J08). For computational efficiency, these expressions were rewritten in the polynomial form that was only valid for S-band radar in which the Rayleigh assumption was satisfied. Later, a more general and exact operator that fully used the T-matrix scattering method was proposed (Jung et al., 2010). This operator was given as the integral of the complex backscattering amplitudes over the size distribution of the precipitation particles (i.e., rainwater, snow, and graupel). In addition to these operators, several complex reflectivity operators in the integral form have also been proposed (Borderies et al., 2018; Caumont et al., 2006; Pfeifer et al., 2008; Ryzhkov et al., 2011; Wattrelot et al., 2014). Some were designed for a specific band of radar (e.g., W band; Borderies et al., 2018), whereas some were designed for the bin microphysics scheme (e.g., Ryzhkov et al., 2011).

Reflectivity operators have been developed both for the variational method (Caumont et al., 2010; Gao and Stensrud, 2012; Hu et al., 2006; Sun and Crook, 1997; Sun and Wang, 2013; Wang et al., 2013b; Wattrelot et al., 2014; Xiao et al., 2007) and for the ensemble Kalman filter method (EnKF; Dawson et al., 2010; Jung et al., 2010, 2008a, b; Putnam et al., 2014; Snook et al., 2011, 2015; Tong and Xue, 2005; Xue et al., 2006). The variational method requires the tangent linear (TL) and adjoint (AD) operators, which are not required by the EnKF (Evensen, 2003). Therefore, complex operators such as those proposed by J08 are often employed in EnKF DA applications. For the variational method, a common approach to avoid using the TL/AD operators is to assimilate the reflectivity-retrieved hydrometeor profiles (Caumont et al., 2010; Wang et al., 2013a; Wattrelot et al., 2014); an alternative is to use the reflectivity as an additional control variable with the ensemble–variational DA approach (Wang and Wang, 2017).

Despite the difficulty, some efforts have been undertaken for reflectivity assimilation with the TL/AD operators (Gao and Stensrud, 2012; Kawabata et al., 2018; Liu et al., 2019; Xiao et al., 2007), and reasonable results have been obtained in terms of hydrometeor analysis and precipitation forecasts. However, none of these studies employed operators as complex as those proposed by J08. Kawabata et al. (2018) adopted the expressions of Zhang et al. (2001) and developed the TL/AD operator for C-band radar but without taking into account the contributions from ice-phase species.

The main purpose of this study is to develop a TL/AD operator based on Jung et al. (2008a) with the contributions of ice-phase precipitation and apply it in a variational DA framework. For convenience, the operator implemented in this study is called RadarVar to represent that it was developed for variational DA and contains ice-phase species. The original J08 operator is called J08orig. The reminder of this paper is organized as follows. In Sect. 2, the J08 operator is reviewed, and its TL and AD operators are derived. The experimental design is given in Sect. 3, and the new operators are verified in Sect. 4. The performance of RadarVar is discussed in Sect. 5, and the conclusions are presented in Sect. 6.

2 Reflectivity operator

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The radar-observed reflectivity, *Z*, is given in logarithmic form as

$$\begin{array}{}\text{(1)}& Z=\mathrm{10}{\mathrm{log}}_{\mathrm{10}}{Z}_{\mathrm{e}},\end{array}$$

where *Z*_{e} is the equivalent reflectivity factor, which is the sum of the
contributions from pure rainwater (*Z*_{r}), dry snow (*Z*_{ds}), dry graupel
(*Z*_{dg}), wet snow (*Z*_{ws}), and wet graupel (*Z*_{wg}) as follows:

$$\begin{array}{}\text{(2)}& {Z}_{\mathrm{e}}={Z}_{\mathrm{r}}+{Z}_{\mathrm{ds}}+{Z}_{\mathrm{dg}}+{Z}_{\mathrm{ws}}+{Z}_{\mathrm{wg}}.\end{array}$$

To compute Eq. (2), the mixing ratios of mixed-phase species (wet snow and wet graupel) are required. However, many widely used microphysics schemes, such as the Lin, WSM6, and Morrison schemes, do not predict or diagnose the mixed-phase species; thus, the amount of rainwater in wet snow or graupel cannot be directly extracted from the model output. To solve this issue, J08 modeled the rain–snow (rain–graupel) mixture using a fraction that is given by

$$\begin{array}{}\text{(3)}& F=[min({q}_{\mathrm{r}}/{q}_{x},{q}_{x}/{q}_{\mathrm{r}}){]}^{\mathrm{0.3}}{F}_{max},\end{array}$$

where *F*_{max} is the maximum fraction, which is 0.5 (0.3) for rain–graupel
(rain–snow) mixtures; *q*_{r} is the mixing ratio of rainwater; and *q*_{x} is
the general form of the mixing ratio of ice-phase species. The subscript
“*x*” can be either “s” for snow or “g” for graupel. With this fraction,
the mixing ratios of pure rainwater, dry snow, dry graupel, and mixed-phase
species are given by

$$\begin{array}{}\text{(4)}& \begin{array}{rl}& {q}_{\mathrm{pr}}=(\mathrm{1}-{F}_{\mathrm{ws}}-{F}_{\mathrm{wg}}){q}_{\mathrm{r}}\\ & {q}_{\mathrm{ds}}=(\mathrm{1}-{F}_{\mathrm{ws}}){q}_{\mathrm{s}}\\ & {q}_{\mathrm{dg}}=(\mathrm{1}-{F}_{\mathrm{wg}}){q}_{\mathrm{g}}\\ & {q}_{\mathrm{ws}}={F}_{\mathrm{ws}}({q}_{\mathrm{s}}+{q}_{\mathrm{r}})\\ & {q}_{\mathrm{wg}}={F}_{\mathrm{wg}}({q}_{\mathrm{g}}+{q}_{\mathrm{r}}),\end{array}\end{array}$$

where the subscripts “ws” and “wg” are added to *F* to represent the
fractions of wet snow and wet graupel, respectively, and the subscripts
“pr”, “ds”, and “dg” represent pure water, dry snow, and dry graupel,
respectively. The mixed-phase density, *ρ*_{wx}, is not a constant and
is parameterized by

$$\begin{array}{}\text{(5)}& {\mathit{\rho}}_{\mathrm{w}x}=(\mathrm{1}-{f}_{\mathrm{w}x}^{\mathrm{2}}){\mathit{\rho}}_{x}+{f}_{\mathrm{w}x}^{\mathrm{2}}{\mathit{\rho}}_{\mathrm{r}},\end{array}$$

with

$$\begin{array}{}\text{(6)}& {f}_{\mathrm{w}x}={\displaystyle \frac{{q}_{\mathrm{r}}}{{q}_{\mathrm{r}}+{q}_{x}}}.\end{array}$$

The subscript “*x*” in *ρ*_{wx}, *ρ*_{x}, and *f*_{wx} represents
either snow (s) or graupel (g), and *f*_{wx} is called the water fraction.

In accordance with J08, all of the contributions are computed by
integrations over the drop size distribution (DSD) weighted by the scatter
cross section determined by the density, shape, and DSD. The DSD is modeled
by an exponential distribution. After performing the integration, the
contribution from pure rainwater, *Z*_{r}, is written in a simple form (Zhang
et al., 2001; Posselt et al., 2015; Kawabata et al., 2018) as follows:

$$\begin{array}{}\text{(7)}& {Z}_{\mathrm{r}}={\displaystyle \frac{\mathrm{4}{\mathit{\lambda}}^{\mathrm{4}}{\mathit{\alpha}}_{\mathrm{ra}}^{\mathrm{2}}{N}_{\mathrm{0}\mathrm{r}}}{{\mathit{\pi}}^{\mathrm{4}}{\left|{K}_{\mathrm{w}}\right|}^{\mathrm{2}}}}{\mathrm{\Lambda}}_{\mathrm{r}}^{-(\mathrm{2}{\mathit{\beta}}_{\mathrm{ra}}+\mathrm{1})}\mathrm{\Gamma}(\mathrm{2}{\mathit{\beta}}_{\mathrm{ra}}+\mathrm{1}),\end{array}$$

where *λ* is the wavelength of the radar, which is 107 mm for S-band
radar, and *N*_{0r} is the intercept parameter of rainwater, which is
8×10^{6} m^{−4} in this study. *N*_{0r} values are typically
fixed (or constant) in single-moment microphysics schemes; for a two-moment
scheme, this value should be determined using the predicted number
concentration. $|{K}_{\mathrm{w}}{|}^{\mathrm{2}}$ is the dielectric factor for
rainwater and is equal to 0.93, and *α*_{ra} and *β*_{ra} are $\mathrm{4.28}\times {\mathrm{10}}^{-\mathrm{4}}$ and 3.04, respectively. The
complete gamma function is written as Γ(…). The slope
parameter of rain, Λ_{r}, is

$$\begin{array}{}\text{(8)}& {\mathrm{\Lambda}}_{\mathrm{r}}=({\displaystyle \frac{\mathit{\pi}{\mathit{\rho}}_{\mathrm{r}}{N}_{\mathrm{0}\mathrm{r}}}{{\mathit{\rho}}_{\mathrm{a}}{q}_{\mathrm{pr}}}}{)}^{{\scriptscriptstyle \frac{\mathrm{1}}{\mathrm{4}}}},\end{array}$$

where *ρ*_{r}=1000 kg m^{−3} is the rain density, *q*_{pr} is
given by Eq. (4), and *ρ*_{a} is the density of air. By substituting
Eq. (8) and the constant parameters into Eq. (7), we can rewrite Eq. (7) as
a function of *q*_{pr} as follows:

$$\begin{array}{}\text{(9)}& {Z}_{\mathrm{r}}\left({q}_{\mathrm{pr}}\right)={P}_{\mathrm{r}}({q}_{\mathrm{pr}}{)}^{\mathrm{1.77}},\end{array}$$

where

$$\begin{array}{}\text{(10)}& {P}_{\mathrm{r}}={\displaystyle \frac{\mathrm{4}{\mathit{\lambda}}^{\mathrm{4}}{\mathit{\alpha}}_{\mathrm{ra}}^{\mathrm{2}}}{{\mathit{\pi}}^{\mathrm{4}}{\left|{K}_{\mathrm{w}}\right|}^{\mathrm{2}}}}\left({\displaystyle \frac{\mathit{\pi}{\mathit{\rho}}_{\mathrm{r}}}{{\mathit{\rho}}_{\mathrm{a}}}}{)}^{-{\scriptscriptstyle \frac{\mathrm{2}{\mathit{\beta}}_{\mathrm{ra}}+\mathrm{1}}{\mathrm{4}}}}\right({N}_{\mathrm{0}\mathrm{r}}{)}^{\mathrm{1}-{\scriptscriptstyle \frac{\mathrm{2}{\mathit{\beta}}_{\mathrm{ra}}+\mathrm{1}}{\mathrm{4}}}}\mathrm{\Gamma}(\mathrm{2}{\mathit{\beta}}_{\mathrm{ra}}+\mathrm{1}).\end{array}$$

The value of *P*_{r} is approximately 4.8×10^{9} with an air
density of 1.0 kg m^{−3}. This value has the same magnitude as those
proposed by Sun and Crook (1997) and Gao and Stensrud (2012).

The contributions from both dry and mixed-phase ice species after integration have the same form but differ in their coefficients. For dry ice species, the contribution is given by

$$\begin{array}{}\text{(11)}& {Z}_{\mathrm{d}x}={\displaystyle \frac{\mathrm{4}\mathrm{\Gamma}\left(\mathrm{7}\right){\mathit{\lambda}}^{\mathrm{4}}{N}_{\mathrm{0}x}}{{\mathit{\pi}}^{\mathrm{4}}{\left|{K}_{\mathrm{w}}\right|}^{\mathrm{2}}}}{\mathrm{\Lambda}}_{\mathrm{d}x}^{-\mathrm{7}}(A{\mathit{\alpha}}_{\mathrm{d}x\mathrm{a}}^{\mathrm{2}}+B{\mathit{\alpha}}_{\mathrm{d}x\mathrm{b}}^{\mathrm{2}}+\mathrm{2}C{\mathit{\alpha}}_{\mathrm{d}x\mathrm{a}}{\mathit{\alpha}}_{\mathrm{d}x\mathrm{b}}),\end{array}$$

where the subscript *x* represents either snow (s) or graupel (g). The
intercept parameters of these species are denoted by *N*_{0x}, the values of
which are 3×10^{6} and 4×10^{5} m^{−4}
for snow and graupel, respectively. Both values are consistent with the
default values of Advanced Regional Prediction System (ARPS) EnKF where the J08 operator was implemented. The
slope parameter in Eq. (11) for either dry snow or dry graupel is written as

$$\begin{array}{}\text{(12)}& {\mathrm{\Lambda}}_{\mathrm{d}x}=({\displaystyle \frac{\mathit{\pi}{\mathit{\rho}}_{x}{N}_{\mathrm{0}x}}{{\mathit{\rho}}_{\mathrm{a}}{q}_{\mathrm{d}x}}}{)}^{{\scriptscriptstyle \frac{\mathrm{1}}{\mathrm{4}}}},\end{array}$$

where *ρ*_{x} is either the density of snow (100 kg m^{−3}) or
graupel (400 kg m^{−3}). The parameters *A*, *B*, and *C* in Eq. (11) are functions
of the mean ($\overline{\mathit{\varphi}}$) and the standard deviation (*σ*) of the canting angle and are given
by

$$\begin{array}{}\text{(13)}& \begin{array}{rl}& A={\displaystyle \frac{\mathrm{1}}{\mathrm{8}}}(\mathrm{3}+\mathrm{4}\mathrm{cos}\mathrm{2}\overline{\mathit{\varphi}}{e}^{-\mathrm{2}{\mathit{\sigma}}^{\mathrm{2}}}+\mathrm{cos}\mathrm{4}\overline{\mathit{\varphi}}{e}^{-\mathrm{8}{\mathit{\sigma}}^{\mathrm{2}}})\\ & B={\displaystyle \frac{\mathrm{1}}{\mathrm{8}}}(\mathrm{3}-\mathrm{4}\mathrm{cos}\mathrm{2}\overline{\mathit{\varphi}}{e}^{-\mathrm{2}{\mathit{\sigma}}^{\mathrm{2}}}+\mathrm{cos}\mathrm{4}\overline{\mathit{\varphi}}{e}^{-\mathrm{8}{\mathit{\sigma}}^{\mathrm{2}}})\\ & C={\displaystyle \frac{\mathrm{1}}{\mathrm{8}}}(\mathrm{1}-\mathrm{cos}\mathrm{4}\overline{\mathit{\varphi}}{e}^{-\mathrm{8}{\mathit{\sigma}}^{\mathrm{2}}}).\end{array}\end{array}$$

According to J08,
$\overline{\mathit{\varphi}}$
is zero for all hydrometeors, and *σ* differs for snow (20^{∘}) and hail (60^{∘}). Here, we assume that *σ*for graupel is
also 60^{∘}. The horizontal reflectivity that is regarded in this
study is not sensitive to the canting angle (will be demonstrated in Sect. 2.4), although the differential reflectivity is sensitive to canting angle
(Aydin and Seliga, 1984). In Eq. (11), *A*, *B*, and *C* are multiplied by
coefficients (*α*_{dxa} and *α*_{dxb}) that describe the
backscattering amplitudes. For dry ice-phase species, these coefficients are
precalculated constants and are listed in Table 1. The coefficients of
graupel are calculated using the backscattering amplitudes (for particle
size <10 mm) in the pyCAPS-PRS v1.1 software (Dawson et al., 2014;
Johnson et al., 2016; Jung et al., 2010; Jung et al., 2008a) provided by the
Center for Analysis and Prediction of Storms (CAPS), and fitted to the
polynomial function of *f*_{wg}. *α*_{dga} and *α*_{dgb} are
the coefficients when *f*_{wg} is zero, which indicates no rainwater.

For brevity, Eq. (11) is rewritten as a function of *q*_{dx} for dry snow and
dry graupel and is given by

$$\begin{array}{}\text{(14)}& {Z}_{\mathrm{d}x}\left({q}_{\mathrm{d}x}\right)={P}_{\mathrm{d}x}{q}_{\mathrm{d}x}^{\mathrm{1.75}},\end{array}$$

where

$$\begin{array}{}\text{(15)}& \begin{array}{rl}{P}_{\mathrm{d}x}=& {\displaystyle \frac{\mathrm{4}\mathrm{\Gamma}\left(\mathrm{7}\right){\mathit{\lambda}}^{\mathrm{4}}{N}_{\mathrm{0}x}^{-\mathrm{0.75}}}{{\mathit{\pi}}^{\mathrm{4}}{\left|{K}_{\mathrm{w}}\right|}^{\mathrm{2}}}}({\displaystyle \frac{\mathit{\pi}{\mathit{\rho}}_{x}}{{\mathit{\rho}}_{\mathrm{a}}}}{)}^{-\mathrm{1.75}}\\ & (A{\mathit{\alpha}}_{\mathrm{d}x\mathrm{a}}^{\mathrm{2}}+B{\mathit{\alpha}}_{\mathrm{d}x\mathrm{b}}^{\mathrm{2}}+\mathrm{2}C{\mathit{\alpha}}_{\mathrm{d}x\mathrm{a}}{\mathit{\alpha}}_{\mathrm{d}x\mathrm{b}}).\end{array}\end{array}$$

The equation for the contribution from mixed-phase species has the same form
as Eq. (11), except that the subscript “d” is replaced by “w” to
represent wet species. The slope parameter for mixed-phase species also has
the same form as Eq. (12), except that the subscript “d” is replaced by
“w”, and *ρ*_{wx} is substituted for *ρ*_{x}. For wet species,
*σ* in *A*, *B*, and *C* is a function of *f*_{w} and *q*_{wg}. Additional
details are given in Sect. 3c of J08. The coefficients that are multiplied
by *A*, *B*, and *C* are functions of *f*_{w} and are written as

$$\begin{array}{}\text{(16)}& \begin{array}{rl}& {\mathit{\alpha}}_{\mathrm{w}x\mathrm{a}}={\mathit{\epsilon}}_{x}\sum _{k=\mathrm{0}}^{n}{P}_{\mathrm{w}x\mathrm{a}k}{f}_{\mathrm{w}x}^{k}\\ & {\mathit{\alpha}}_{\mathrm{w}x\mathrm{b}}={\mathit{\epsilon}}_{x}\sum _{k=\mathrm{0}}^{n}{P}_{\mathrm{w}x\mathrm{b}k}{f}_{\mathrm{w}x}^{k},\end{array}\end{array}$$

where “*x*” is “s” (g) for snow (graupel), *ε*_{x} is
10^{−4} (10^{−3}) for snow (graupel), *P*_{wxak} and
*P*_{wxbk} are precalculated constants for S-band radar, the value of
*n* is 6, and the superscript *k* denotes the index of these constants. All these
values are based on J08, except for those of graupel, which are computed using
the same method mentioned in Sect. 2.1.2. The values of *P*_{wxak} and
*P*_{wxbk} are listed in Table 2.

To simplify the derivation of the TL/AD operators, we rewrite Eq. (11) as a
function of the mixed-phase mixing ratio (*q*_{wx}) and the water fraction
(*f*_{w}) as follows:

$$\begin{array}{}\text{(17)}& {Z}_{\mathrm{w}x}({q}_{\mathrm{w}x},{f}_{\mathrm{w}x})={P}_{\mathrm{w}x}{q}_{\mathrm{w}x}^{\mathrm{1.75}}{\mathit{\epsilon}}_{x}^{\mathrm{2}}\sum _{k=\mathrm{0}}^{\mathrm{2}n}{P}_{xk}{f}_{\mathrm{w}x}^{k},\end{array}$$

where the coefficients *P*_{wx} and *P*_{xk} are given by

$$\begin{array}{}\text{(18)}& {P}_{\mathrm{w}x}={\displaystyle \frac{\mathrm{4}\mathrm{\Gamma}\left(\mathrm{7}\right){\mathit{\lambda}}^{\mathrm{4}}{N}_{\mathrm{0}x}^{-\mathrm{0.75}}}{{\mathit{\pi}}^{\mathrm{4}}{\left|{K}_{\mathrm{w}}\right|}^{\mathrm{2}}}}({\displaystyle \frac{\mathit{\pi}{\mathit{\rho}}_{\mathrm{w}x}}{{\mathit{\rho}}_{\mathrm{a}}}}{)}^{-\mathrm{1.75}},\end{array}$$

and

$$\begin{array}{}\text{(19)}& {P}_{xk}=A{P}_{Axk}+B{P}_{Bxk}+\mathrm{2}C{P}_{Cxk},\end{array}$$

respectively. *P*_{Axk}, *P*_{Bxk}, and *P*_{Cxk} in Eq. (19)
are given by

$$\begin{array}{}\text{(20)}& \begin{array}{rl}& {P}_{Axk}=\left\{\begin{array}{c}{\sum}_{i=\mathrm{0}}^{k}{P}_{\mathrm{w}x\mathrm{a}i}{P}_{\mathrm{w}x\mathrm{a}(k-i)}(k\le n)\\ {\sum}_{i=k-n}^{n}{P}_{\mathrm{w}x\mathrm{a}i}{P}_{\mathrm{w}x\mathrm{a}(k-i)},(k>n)\end{array}\right.\\ & {P}_{Bxk}=\left\{\begin{array}{c}{\sum}_{i=\mathrm{0}}^{k}{P}_{\mathrm{w}x\mathrm{b}i}{P}_{\mathrm{w}x\mathrm{b}(k-i)},(k\le n)\\ {\sum}_{i=k-n}^{n}{P}_{\mathrm{w}x\mathrm{b}i}{P}_{\mathrm{w}x\mathrm{b}(k-i)}(k>n)\end{array}\right.\\ & {P}_{Cxk}=\left\{\begin{array}{c}{\sum}_{i=\mathrm{0}}^{k}{P}_{\mathrm{w}x\mathrm{a}i}{P}_{\mathrm{w}x\mathrm{b}(k-i)},(k\le n)\\ {\sum}_{i=k-n}^{n}{P}_{\mathrm{w}x\mathrm{a}i}{P}_{\mathrm{w}x\mathrm{b}(k-i)},(k>n),\end{array}\right.\end{array}\end{array}$$

where *P*_{wxai} and *P*_{wxbi} are precalculated constants
in Eq. (16) and are listed in Table 2. The subscript “*x*” in these constant
coefficients represents either snow (s) or graupel (g). The derivations of
Eqs. (17) to (20) are given in the Appendix.

Because RadarVar is highly nonlinear and complex, performing the derivation
for every nonconstant variable in this operator is difficult. In addition,
some components of RadarVar (e.g., the fraction *F* in Eq. 3) are
discontinuous and may cause serious convergence problems in the minimization
(Janisková and Lopez, 2013; Janisková et al., 1999). Although this
issue can be addressed by performing regularization for the discontinuous
components in RadarVar, it is beyond the scope of this study. Here, we
assumed that five variables in RadarVar are not changed in the minimization:
(i) the air density, (ii) the fraction *F*, (iii) the intercept parameter, (iv) the
standard deviation of the canting angle *σ*, and (v) the density of the
mixed-phase species. The air density is held constant for simplification and
to focus on the impact of the changes in the hydrometeors. The fraction *F* is
assumed to remain unchanged because of its second-order discontinuity at the
point that *q*_{x} is equal to *q*_{r}. The intercept parameter is constant
because RadarVar was currently designed for single-moment microphysics
schemes. Although multi-moment microphysics schemes are more realistic
because they predict the number density of hydrometeors, single-moment
microphysics schemes are still widely used to compute reflectivity and the
polarization variables (e.g., Posselt et al., 2015). For simplification, the
standard deviation of the canting angle and the density of the mixed-phase
species remain unchanged in the minimization. These assumptions are
discussed in Sect. 4.

Considering the assumptions presented above, *P*_{r} in Eq. (9) becomes a
constant in the minimization. Therefore, the linearized form of Eq. (9) for
*q*_{pr} is given by

$$\begin{array}{}\text{(21)}& \begin{array}{rl}\mathit{\delta}{Z}_{\mathrm{r}}\left({q}_{\mathrm{pr}}\right)& ={\displaystyle \frac{\partial {Z}_{\mathrm{r}}\left({q}_{\mathrm{pr}}\right)}{\partial {q}_{\mathrm{pr}}}}{\displaystyle \frac{\partial {q}_{\mathrm{pr}}}{\partial {q}_{\mathrm{r}}}}\mathit{\delta}{q}_{\mathrm{r}}\\ & =\mathrm{1.77}{P}_{\mathrm{r}}\left({q}_{\mathrm{pr}}{)}^{\mathrm{0.77}}\right(\mathrm{1}-{F}_{\mathrm{ws}}-{F}_{\mathrm{wg}})\mathit{\delta}{q}_{\mathrm{r}}\end{array}.\end{array}$$

For dry snow and graupel, the linearized form of Eq. (14) is given by

$$\begin{array}{}\text{(22)}& \begin{array}{rl}\mathit{\delta}{Z}_{\mathrm{d}x}\left({q}_{\mathrm{d}x}\right)=& {\displaystyle \frac{\partial {Z}_{\mathrm{d}x}}{\partial {q}_{\mathrm{d}x}}}{\displaystyle \frac{\partial {q}_{\mathrm{d}x}}{\partial {q}_{x}}}\mathit{\delta}{q}_{x}\\ & =\mathrm{1.75}{P}_{\mathrm{d}x}{q}_{\mathrm{d}x}^{\mathrm{0.75}}(\mathrm{1}-{F}_{\mathrm{w}x})\mathit{\delta}{q}_{x}\end{array}.\end{array}$$

The linearization of Eq. (17) can be categorized into two parts, which
represent the variations in *Z*_{x} caused by changes in *q*_{wx} and
*f*_{wx}, respectively. The linear equation of Eq. (17) is written as

$$\begin{array}{}\text{(23)}& \begin{array}{rl}& \mathit{\delta}{Z}_{\mathrm{w}x}({q}_{\mathrm{w}x},{f}_{\mathrm{w}x})={\displaystyle \frac{\partial {Z}_{\mathrm{w}x}}{\partial {q}_{\mathrm{w}x}}}({\displaystyle \frac{\partial {q}_{\mathrm{w}x}}{\partial {q}_{x}}}\mathit{\delta}{q}_{x}\\ & \phantom{\rule{1em}{0ex}}+{\displaystyle \frac{\partial {q}_{\mathrm{w}x}}{\partial {q}_{\mathrm{r}}}}\mathit{\delta}{q}_{\mathrm{r}})+{\displaystyle \frac{\partial {Z}_{\mathrm{w}x}}{\partial {f}_{\mathrm{w}x}}}({\displaystyle \frac{\partial {f}_{\mathrm{w}x}}{\partial {q}_{x}}}\mathit{\delta}{q}_{x}+{\displaystyle \frac{\partial {f}_{\mathrm{w}x}}{\partial {q}_{\mathrm{r}}}}\mathit{\delta}{q}_{\mathrm{r}})\\ & =({\displaystyle \frac{\partial {Z}_{\mathrm{w}x}}{\partial {q}_{\mathrm{w}x}}}{\displaystyle \frac{\partial {q}_{\mathrm{w}x}}{\partial {q}_{\mathrm{r}}}}+{\displaystyle \frac{\partial {Z}_{\mathrm{w}x}}{\partial {f}_{\mathrm{w}x}}}{\displaystyle \frac{\partial {f}_{\mathrm{w}x}}{\partial {q}_{\mathrm{r}}}})\mathit{\delta}{q}_{\mathrm{r}}\\ & \phantom{\rule{1em}{0ex}}+({\displaystyle \frac{\partial {Z}_{\mathrm{w}x}}{\partial {q}_{\mathrm{w}x}}}{\displaystyle \frac{\partial {q}_{\mathrm{w}x}}{\partial {q}_{x}}}+{\displaystyle \frac{\partial {Z}_{\mathrm{w}x}}{\partial {f}_{\mathrm{w}x}}}{\displaystyle \frac{\partial {f}_{\mathrm{w}x}}{\partial {q}_{\mathrm{r}}}})\mathit{\delta}{q}_{x}\\ & =\mathit{\left\{}\mathrm{1.75}{P}_{\mathrm{w}x}{q}_{\mathrm{w}x}^{\mathrm{0.75}}{F}_{\mathrm{w}x}\right({\mathit{\epsilon}}_{x}^{\mathrm{2}}\sum _{k=\mathrm{0}}^{\mathrm{2}n}{P}_{xk}{f}_{\mathrm{w}x}^{k})\\ & +{P}_{\mathrm{w}x}{q}_{\mathrm{w}x}^{\mathrm{1.75}}\left[{\mathit{\epsilon}}_{x}^{\mathrm{2}}\sum _{k=\mathrm{0}}^{\mathrm{2}n}{P}_{xk}k{f}_{\mathrm{w}x}^{k}\right({\displaystyle \frac{\mathrm{1}}{{q}_{\mathrm{r}}}}-{\displaystyle \frac{\mathrm{1}}{{q}_{\mathrm{r}}+{q}_{x}}}\left)\right]\mathit{\}}\mathit{\delta}{q}_{\mathrm{r}}\\ & +\mathit{\left\{}\mathrm{1.75}{P}_{\mathrm{w}x}{q}_{\mathrm{w}x}^{\mathrm{0.75}}{F}_{\mathrm{w}x}\right({\mathit{\epsilon}}_{x}^{\mathrm{2}}\sum _{k=\mathrm{0}}^{\mathrm{2}n}{P}_{xk}{f}_{\mathrm{w}x}^{k})\\ & +{P}_{\mathrm{w}x}{q}_{\mathrm{w}x}^{\mathrm{1.75}}\left[{\mathit{\epsilon}}_{x}^{\mathrm{2}}\sum _{k=\mathrm{0}}^{\mathrm{2}n}{P}_{xk}k{f}_{\mathrm{w}x}^{k}\right(-{\displaystyle \frac{\mathrm{1}}{{q}_{\mathrm{r}}+{q}_{x}}}\left)\right]\mathit{\}}\mathit{\delta}{q}_{x},\end{array}\end{array}$$

where the subscript “*x*” represents either snow (s) or graupel (g). Using s
(g) to replace the subscript “*x*” in Eq. (23), we can obtain the tangent
linear operator of the contribution from wet snow (wet graupel).

The linearization of Eq. (1) is given by

$$\begin{array}{}\text{(24)}& \mathit{\delta}Z=\mathrm{10}{\displaystyle \frac{\mathrm{1}}{{Z}_{\mathrm{e}}\mathrm{ln}\mathrm{10}}}\mathit{\delta}{Z}_{\mathrm{e}},\end{array}$$

where *δ**Z*_{e} is the sum of *δ**Z*_{r}, *δ**Z*_{ds},
*δ**Z*_{dg}, *δ**Z*_{ws}, and *δ**Z*_{wg}. Note that
*Z*_{e} cannot be zero. Moreover, a too-small *Z*_{e} may result in an extremely
large gradient during the minimization, which is undesirable. Therefore, the
accepted minimum *Z*_{e} is set to 1.0 in the current RadarVar. When the
background value is smaller than this minimum value, DA system will discard
the corresponding observation to prevent a large gradient. This minimum
value can be smaller to ingest more observation and will be tuned in future
work.

The adjoint operator is the transpose of the tangent linear operator.
Because the tangent linear operator is applied to the model variables
*q*_{r}, *q*_{s}, and *q*_{g}, the adjoint operator is written for these
variables. First, the adjoint operator is written for Eq. (24). This
operator has the following form:

$$\begin{array}{}\text{(25)}& \mathit{\delta}{Z}_{\mathrm{e}}^{\mathrm{A}}=\mathrm{10}{\displaystyle \frac{\mathrm{1}}{{Z}_{\mathrm{e}}\mathrm{ln}\mathrm{10}}}\mathit{\delta}Z,\end{array}$$

where the superscript “A” means adjoint.

For rainwater in Eq. (21), the adjoint operator is given by

$$\begin{array}{}\text{(26)}& \mathit{\delta}{q}_{\mathrm{r}}^{\mathrm{A}}=\mathit{\delta}{q}_{\mathrm{r}}^{\mathrm{A}}+\mathrm{1.77}{P}_{\mathrm{r}}\left({q}_{\mathrm{pr}}{)}^{\mathrm{0.77}}\right(\mathrm{1}-{F}_{\mathrm{ws}}-{F}_{\mathrm{wg}})\mathit{\delta}{Z}_{\mathrm{e}}^{\mathrm{A}}.\end{array}$$

The parameter ${q}_{\mathrm{r}}^{\mathrm{A}}$ on the right-hand side of Eq. (26) is the accumulated
${q}_{\mathrm{r}}^{\mathrm{A}}$
before computing Eq. (26). This rule is also valid for *q*_{x}.

The adjoint operator of Eq. (22) is given by

$$\begin{array}{}\text{(27)}& \mathit{\delta}{q}_{x}^{\mathrm{A}}=\mathit{\delta}{q}_{x}^{\mathrm{A}}+\mathrm{1.75}{P}_{\mathrm{d}x}{q}_{\mathrm{d}x}^{\mathrm{0.75}}(\mathrm{1}-{F}_{\mathrm{w}x})\mathit{\delta}{Z}_{\mathrm{e}}^{\mathrm{A}}.\end{array}$$

Because Eq. (23) is the derivation with respect to both *q*_{r} and
*q*_{x}, the adjoint operator of Eq. (23) contains two parts: one for
rainwater and the other for ice species. For rainwater involved in Eq. (23),
the adjoint operator is given by

$$\begin{array}{}\text{(28)}& \begin{array}{rl}\mathit{\delta}{q}_{\mathrm{r}}^{\mathrm{A}}=& \mathit{\delta}{q}_{\mathrm{r}}^{\mathrm{A}}+\mathrm{1.75}{P}_{\mathrm{w}x}{q}_{\mathrm{w}x}^{\mathrm{0.75}}{F}_{\mathrm{w}x}\left({\mathit{\epsilon}}_{x}^{\mathrm{2}}\sum _{k=\mathrm{0}}^{\mathrm{2}n}{P}_{xk}{f}_{\mathrm{w}x}^{k}\right)\mathit{\delta}{Z}_{\mathrm{e}}^{\mathrm{A}}\\ & +{P}_{\mathrm{w}x}{q}_{\mathrm{w}x}^{\mathrm{1.75}}\left[{\mathit{\epsilon}}_{x}^{\mathrm{2}}\sum _{k=\mathrm{0}}^{\mathrm{2}n}{P}_{xk}k{f}_{\mathrm{w}x}^{k}\right({\displaystyle \frac{\mathrm{1}}{{q}_{\mathrm{r}}}}-{\displaystyle \frac{\mathrm{1}}{{q}_{\mathrm{r}}+{q}_{x}}}\left)\right]\mathit{\delta}{Z}_{\mathrm{e}}^{\mathrm{A}}.\end{array}\end{array}$$

For ice species in Eq. (23), the adjoint operator is given by

$$\begin{array}{}\text{(29)}& \begin{array}{rl}\mathit{\delta}{q}_{x}^{\mathrm{A}}=& \mathit{\delta}{q}_{x}^{\mathrm{A}}+\mathrm{1.75}{P}_{\mathrm{w}x}{q}_{\mathrm{w}x}^{\mathrm{0.75}}{F}_{\mathrm{w}x}\left({\mathit{\epsilon}}_{x}^{\mathrm{2}}\sum _{k=\mathrm{0}}^{\mathrm{2}n}{P}_{xk}{f}_{\mathrm{w}x}^{k}\right)\mathit{\delta}{Z}_{\mathrm{e}}^{\mathrm{A}}\\ & +{P}_{\mathrm{w}x}{q}_{\mathrm{w}x}^{\mathrm{1.75}}\left[{\mathit{\epsilon}}_{x}^{\mathrm{2}}\sum _{k=\mathrm{0}}^{\mathrm{2}n}{P}_{xk}k{f}_{\mathrm{w}x}^{k}\right(-{\displaystyle \frac{\mathrm{1}}{{q}_{\mathrm{r}}+{q}_{x}}}\left)\right]\mathit{\delta}{Z}_{\mathrm{e}}^{\mathrm{A}}.\end{array}\end{array}$$

Since RadarVar is highly nonlinear, understanding its response to changes in
*q*_{r}, *q*_{s}, and *q*_{g} assists in the analysis of DA results using this
operator. The response functions for Eqs. (9), (14), and (17) are
plotted in Fig. 1. Figure 1b is a two-dimensional plot because Eq. (17)
involves two kinds of hydrometeors. Figure 1a shows that the reflectivity
changes more rapidly for all three hydrometeors when the mixing ratios are
less than 0.5 g kg^{−1}. As the mixing ratios increase to 2.0 g kg^{−1} or greater, the relationship between the reflectivity and the mixing ratio
is approximately linear. This feature indicates that the reflectivity is
more sensitive at small mixing ratios, and it also implies that the tangent
linear approximation may give larger errors when the background reflectivity
is small.

In addition, the reflectivity contribution from wet snow increases more
substantially than that from dry snow when *q*_{s} or *q*_{r} are in the range
of 0–0.5 g kg^{−1}. Figure 1b shows that the reflectivity reaches 35 dBZ
when both *q*_{s} and *q*_{r} are approximately 0.2 g kg^{−1}, while this
reflectivity value requires *q*_{s} of ∼1.2 g kg^{−1} for
dry snow. This result is expected because many observation studies (e.g.,
Zhang et al., 2008) have shown that wet snow causes a bright band (large
reflectivity) in the melting layer. This result also implies that the
approximation error in the melting layer could be large.

3 Data and experimental design

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This study focuses on a precipitation case that occurred in the northern US. The precipitation initiated at approximately 21:00 Z on 1 June 2018, when convective cells formed near the border between South Dakota and Nebraska. By 00:00 Z on 2 June 2018, these cells had developed into a linear convective system that was approximately 300 km long in the northeast–southwest direction and stretched from south of South Dakota to northern Nebraska, as shown in Fig. 2. Note that there is also a weaker precipitation system near the north boundary of the domain. The top of the convective system at this time, identified by reflectivity greater than 5 dBZ, reached 16 km a.g.l. This convective line developed further and moved to southeast Nebraska from 00:00 to 04:00 Z. During this period, a bow echo was observed on the radar mosaic provided by the National Centers for Environmental Information (NCEI). By 08:00 Z, the convective line had moved to the northern border of Kansas, followed by a large area of stratiform clouds that covered eastern Nebraska. The precipitation caused by this convective system lasted for nearly 20 h and ended at approximately 18:00 Z on 2 June 2018.

Version 3.9.1 of the Weather Research and Forecasting (WRF; Skamarock et
al., 2018) model was employed. All of the experiments were performed on a
$\mathrm{450}\times \mathrm{450}\times \mathrm{42}$ domain centered at 41^{∘} N,
96^{∘} W, in eastern Nebraska (Fig. 2). The horizontal grid spacing
was 3 km. The terrain-following vertical grid was employed with the model
top at 50 hPa. All of the experiments used the same physical
parameterizations: no cumulus parameterization, the Thompson microphysics
scheme (Thompson et al., 2004),
the Rapid Radiative Transfer Model for general circulation models (RRTMG) longwave and shortwave radiation
scheme (Iacono et al., 2008;
Mlawer et al., 1997), and the Unified Noah
land-surface model (Chen and Dudhia, 2001). Note that in the current RadarVar
implementation, the intercept parameters are fixed, while they
spatiotemporally vary in the Thompson scheme. This inconsistency may increase
the adjustment time for model initialization. However, this issue is
secondary in the present work because no improvement in terms of forecast
skill which will be introduced was found in our early tests using a
single-moment microphysics scheme with the density and intercept parameters
being identical to RadarVar. The primary DA issue in this study is the poor
background quality (due to no hydrometeor in Global Forecast
System (GFS) analysis or the precipitation displacement). The inconsistency between the operator and
microphysics scheme will be considered in the future. The initial conditions
and the lateral boundary conditions were generated with the GFS data at 00:00 Z on 2 June 2018.

RadarVar was implemented in the WRF data assimilation (WRFDA) (Barker et
al., 2012) system. To perform the variational DA with this newly developed
radar operator, it is necessary to generate the background error covariance
matrix with *q*_{r}, *q*_{s}, and *q*_{g} as part of the control variables. The
generalized software package for the background error covariance statistics
(GEN_BE) developed by Descombes et al. (2015) was used. The
GEN_BE package can generate the univariate background error
statistics for 11 variables, including these three hydrometeors. The
background error statistics were computed using the National Meteorological
Center (NMC) method (Parrish and Derber, 1992), which uses pairs of the
differences between the 12 and 24 h forecasts. In total, 27 d
forecasts from 20 May to 15 June 2018 were employed to generate the
background error covariance.

The background error statistics for *q*_{r}, *q*_{s}, and *q*_{g} are shown in
Fig. 3. The vertical distributions of the background error's standard
deviation (Fig. 3a, b, c) are consistent with those of the corresponding
hydrometeor profiles: the error of the rainwater mainly appears in the lower
levels, while those of snow and graupel mainly exist in the upper levels.
The graupel may fall from the upper levels into the lower levels, so the
graupel error has a broad vertical distribution. The horizontal correlation
length scales of the background errors are often less than four grids
(<12 km), and the vertical correlation of each hydrometeor can be
large at the associated precipitation levels. These spatial correlations of
the hydrometeor errors determine the remote horizontal and vertical
influences of the observed reflectivity.

Radar data at 00:00 and 01:00 Z on 2 June 2018 were selected to evaluate the radar
operator in a variational analysis framework because the convection was
sufficiently deep to contain ice-phase species. To fully cover the
convective system at 00:00 Z, data from KABR, KFSD, KLNX, KOAX, KUDX, and KUEX
were used, and KLNX was the closest radar from the convective line (Fig. 2).
These radars were located in Nebraska and South Dakota. The radar data were
stored in level-II format and converted to WRFDA format using a modified
88D2ARPS package, which is widely used in radar DA studies (Putnam et al.,
2014; Snook et al., 2011, 2012). During this conversion, the radar data were
also horizontally remapped to the model grids but remained at the radar
elevations in the vertical direction; in other words, the horizontal
resolution of the radar data after the conversion was consistent with that
of the model. To be consistent with the work using the J08 operator (Jung et
al., 2008b), the observation error of the reflectivity was set to 2.0 dBZ.
Our early tests using different observation errors indicated that the errors
of the analysis reflectivity were comparable when using reflectivity errors
ranging from 0.5 to 2.0 dBZ. For computational efficiency, we selected
the remapped data every two grids in both the *x* and *y* directions for the DA.

The NCEP gridded stage IV (ST4) dataset (Lin and Mitchell, 2005) was used for the precipitation forecast verification. ST4 data with a horizontal resolution of 4 km were interpolated into the 3 km model grid mesh to evaluate the precipitation prediction. At each model grid, the interpolated value was the weighted average of the ST4 data within 10 km of the grid; these data were weighted by the square of the inverse of the distance between the model grid and the ST4 data location.

As the first attempt to implement and apply RadarVar in WRFDA, this study focused on the quality of the analysis using the univariate three-dimensional variational (3D-Var) DA method in terms of the root mean square difference (RMSD) against the observed reflectivity and the similarity between the observed reflectivity distributions and the analysis. The forecast performance is the secondary concern and will be explored more thoroughly in a future study with multivariate analysis using more advanced DA techniques.

All of the DA experiments analyzed only rainwater, snow, and graupel by assimilating only the radar reflectivity observations. The first DA experiment, called Exp_ref, is considered the benchmark experiment; it mostly used the default configurations of WRFDA-3D-Var, except the number of outer loops was set to six, and the number of maximum iterations in each outer loop was set to 150. More outer loops were necessary due to inaccurate background hydrometeors and the high nonlinearity of the radar operator. To determine the tradeoff between the analysis quality and computational cost, two variants of Exp_ref were conducted with 50 and 100 inner iterations. In each experiment, the radar DA analyses were performed at 00:00 and 01:00 Z. The background for the 00:00 Z analysis was interpolated from the GFS analysis with zeros for the hydrometeor fields, and the background for the 01:00 Z analysis was the 1 h WRF forecast from the 00:00 Z analysis with more realistic hydrometeor fields.

Note that TL/AD of RadarVar will not be able to create reflectivity
increments with the zero-hydrometeor background (serves as the base state of
TL/AD in the first outer loop), which is the case for the 00:00 Z analysis. An
approach to address this issue is to reset the zero background values of *q*_{r},
*q*_{s}, and *q*_{g} to small values that can range from 10^{−9} to
10^{−6} kg kg^{−1} (e.g., Wang and Wang, 2017). However, this approach
will result in the fraction *F* being a constant, while it is expected that F will
peak near the middle of the melting layer. Therefore, we introduced a
hydrometeor preprocessing step before performing the analysis, which
constructs a new background with the weighted sum of the radar-retrieved
hydrometeor mixing ratios and their background counterparts. The hydrometeor
retrieval followed the procedure that is available in WRFDA, which is based
on Gao and Stensrud (2012). The weight coefficients are arbitrarily set to
0.1 for the retrieval part and to 0.9 for the background. The small weight
for the retrieval part was used to minimize the impact of the retrieval,
mainly to ensure a nonzero background. In addition, current RadarVar cannot
work with the weight coefficient of the retrieval part being smaller than
$\mathrm{6}\times {\mathrm{10}}^{-\mathrm{4}}$ if the background contains no hydrometeor. A larger
weight coefficient of the retrieval part (e.g., 0.5) reduces the difference
between the background and the observation, which weakens the impact of
direct DA using RadarVar and is contradictory to the purpose of this study.
The hydrometeor preprocessing was performed at both 00:00 and 01:00 Z in
Exp_ref as a reference.

To examine the analysis performance with a bad background, the Exp_ref analysis at 00:00 Z was also run with a very small retrieval weight of $\mathrm{6}\times {\mathrm{10}}^{-\mathrm{4}}$. In addition, the impact of the hydrometeor preprocessing on a relatively “good” background (01:00 Z) was examined by comparing it with an experiment without hydrometeor preprocessing.

In several previous studies (Ban et al., 2017; Choi et al., 2017; e.g., Shen and Min, 2015), the horizontal correlation length scale factor of the background error had a large impact on the analysis. Therefore, two additional experiments, Exp_ls0.5 and Exp_ls0.125, were performed at 00:00 Z with the length scale factors of 0.5 and 0.125, respectively.

Short-term forecasts from some of these analyses and from the GFS analysis (referred to as the “noDA” experiment) were also carried out and evaluated.

4 Radar operator validation

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Before evaluating the performance of RadarVar in WRFDA-3D-Var, we first examined the consistency between J08orig and RadarVar. Because RadarVar follows the J08 operator, the operator implemented in ARPS EnKF (Jung et al., 2008a) was used to serve as the J08orig operator. To be comparable to J08orig operator, the coefficients of graupel listed in Tables 1 and 2, as well as the intercept parameter and hydrometeor density, are replaced by those listed in J08, which were designed for hail. These hail-associated coefficients are used only in Sect. 4 for comparison. The noDA 4 h forecast initialized at 00:00 Z was used as the input of the radar operators. The results, which are shown in Fig. 4, indicate that the difference between J08orig and RadarVar is small and acceptable. The small difference is likely caused by the subtle programming differences between the two software packages.

To verify whether RadarVar is sensitive to the unchanged variables during
the minimization (see Sect. 2b), four tests were conducted. The same noDA
4 h forecast was used. In these tests, *q*_{r}, *q*_{s}, and *q*_{g} were
randomly perturbed with standard deviations proportional to their input
values; in other words, a large background mixing ratio caused a large
perturbation. The tests called F_unprt, rhom_unprt, and SD_unprt represent that the fraction *F*, the mixed
form density, and the standard deviation of canting angle, respectively,
were unperturbed (i.e., fixed input calculated from the forecast input). The
test called all_prt denotes that all of the variables in
RadarVar were calculated using perturbed mixing ratios. The standard
deviation of the perturbation was set to 10 % of the background value;
thus, the maximum perturbation could be large, as shown in Fig. 5a. Figure 5
shows that the reflectivities computed in F_unprt,
rhom_unprt, and SD_unprt do not differ
significantly from those computed in all_prt. This result
indicates that keeping these variables unchanged during the minimization is
an acceptable approximation. The most noticeable difference occurs in the
middle layer, which is marked in red circles that plot off the diagonal line
by several dBZ (Fig. 5c), but there are few of these samples.

The tangent linear operator of RadarVar was verified through a ratio, which is given by

$$\begin{array}{}\text{(30)}& {\displaystyle \frac{\left|H(\mathbf{x}+\mathit{\epsilon}\mathit{\delta}\mathbf{x})-H\left(\mathbf{x}\right)\right|}{\mathit{\epsilon}\left|\mathbf{H}\left(\mathit{\delta}\mathbf{x}\right)\right|}}=\mathrm{1}+O\left(\mathit{\epsilon}\right),\end{array}$$

where *H* and **H** represent the nonlinear operator and the corresponding
TL version, respectively, **x** is the vector of the model state
variables (*q*_{r}, *q*_{s}, *q*_{g}), whose perturbation is denoted by
*δ***x**, and *ε* is the perturbation magnitude and is
greater than zero; *δ***x** used the perturbations generated for
all_prt. Table 3 shows that the tangent linear operator is
sufficiently accurate with a ratio close to 1.0.

A correct adjoint operator must satisfy the relationship that is given by

$$\begin{array}{}\text{(31)}& (\mathbf{H}\mathit{\delta}\mathbf{x}{)}^{\mathrm{T}}\mathbf{H}\mathit{\delta}\mathbf{x}=\mathit{\delta}{\mathbf{x}}^{\mathrm{T}}{\mathbf{H}}^{\mathrm{T}}(\mathbf{H}\mathit{\delta}\mathbf{x}).\end{array}$$

The meanings of all of the symbols in this equation are consistent with
those in Eq. (30), and **H**^{T} is the adjoint operator.
All of the perturbations used for the tangent linear test were adopted in
the adjoint test. In the double precision test, there were 14 identical
digits on both sides of Eq. (31); in the single precision test, there were seven
identical digits.

5 Results

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The Exp_ref analyses (six outer loops, 150 inner iterations,
and 0.1 weight for the retrieval part) are first examined in terms of the
radar reflectivity and the mixing ratios of rain, snow, and graupel. As
expected, the analyzed reflectivity agrees much more closely with the
observed reflectivity than the background reflectivity for both analysis
times (00:00 and 01:00 Z) (Fig. 6). In addition, considering that the 00:00 Z
background bias is much larger than that at 01:00 Z, the comparable analysis
error for both times indicates that the analysis is generally relatively
insensitive to the initial background. However, a small number of points in
the analysis have zero reflectivity, while the corresponding observations
can be greater than 10 dBZ (Fig. 6b, d). Further examination indicates that
these failed points are related to the locations with very small background
values of *q*_{r}, *q*_{s}, and *q*_{g}, where the nonlinearity of the
radar operator and the deficiency of the TL/AD operator are more pronounced.

Figure 7 shows the horizontal distributions of the observed and analyzed reflectivities at 2 km, 4 km (melting layer), and 6 km a.g.l. In general, they match well in observed areas with a weaker analysis at 00:00 Z, which is likely caused by the bad background. Spurious echoes appear over unobserved areas in the analyses at both 00:00 and 01:00 Z and most likely resulted from the spatial correlations in the background error covariance; these correlations allow the propagation of information from observed areas to unobserved areas both horizontally and vertically. This result implies that the statistical correlation length scales obtained from a 1-month forecast sample may be too large for this squall line case. The results of tuning the horizontal correlation length scales will be given in Sect. 5.4. Another cause of these spurious echoes is that non-precipitation echoes were not assigned in the observation data in this study such that DA has no impact outside the observed convective area. An approach to suppress the spurious echoes is to determine the non-precipitation points, assign a specific value like 0 dBZ to these points, and assimilate these non-precipitation echoes. The non-precipitation echoes will be considered in the future.

The 00:00 and 01:00 Z analyses of *q*_{r}, *q*_{s}, and *q*_{g} at three model levels
are shown in Fig. 8. The direct assimilation of the reflectivity data using
RadarVar successfully retrieved the lower level rain, the upper level snow
or graupel, and mixed rain/snow and/or rain/graupel in the melting layer
(model level 15). Note that the analysis increment can be created only at
levels where the SD of the background error is larger than zero (see Fig. 3).

Figure 9 shows the cost function and the norm of its gradient as a function of the number of inner iterations for the first, third, and sixth outer loops. For the 00:00 Z Exp_ref analysis, both the cost function and the gradient norm decrease rapidly in the first outer loop due to the large adjustment from the bad initial background. Using the improved guess after two outer loops, the third outer loop starts from an ∼85 % smaller cost function, which is then reduced more gradually with increasing iterations. Performing more outer loops does not further reduce the cost function substantially, and outer loop 6 even has a slightly larger cost function than that of outer loop 3. Similar behavior can also be observed in the 01:00 Z analysis, but performing more than three outer loops can further reduce the cost function to a small extent. This indicates that performing six outer loops may not be necessary and that two or three outer loops may be sufficient.

To more quantitatively measure the impacts of the number of outer loops and
inner iterations, the correlation coefficients between the
Exp_ref analysis (i.e., six outer loops and 150 iterations in
each loop) and the analyses with one to five outer loops and 50/100/150 inner
iterations in each loop are calculated and shown in Fig. 10. In the 00:00 Z
analysis, the correlation coefficients of *q*_{r} and *q*_{g} are already
greater than 0.9 after the first outer loop, and using 50 or 100 inner
iterations also results in good agreement with the Exp_ref
analysis for *q*_{r} and *q*_{g}. However, this is not the case for *q*_{s},
which is likely an indication of a bad *q*_{s} background (0.1 of the
retrieved values). Given that the correlation coefficients of reflectivity
reach 0.9 after the second outer loop, the low correlation coefficients of
*q*_{s} also imply that it is difficult to distinguish the contributions
from ice-phase species. Even with a more realistic background at 01:00 Z, the
issue of the *q*_{s} analysis with less iterations and outer loops (Fig. 10b)
still exists, but the higher correlation coefficient of the run with
150 iterations after four outer loops, compared to the counterparts in the 00:00 Z
analysis, indicates the importance of the background quality. Note that the
hydrometeor's phase information could be better determined by assimilating
polarization measurements from dual-polarization radar, which will be
explored in a future study.

To further investigate the sensitivity of the analysis to the background quality, additional analyses without the hydrometeor preprocessing step were performed at 00:00 and 01:00 Z. At 00:00 Z, the nonzero background was constructed by using a very small weight ($\mathrm{7}\times {\mathrm{10}}^{-\mathrm{4}}$) for the retrievals. At 01:00 Z, the background is simply taken from the 1 h WRF forecast. Compared to Fig. 6b, the analysis at 00:00 Z (Fig. 11b) has many more failed points (i.e., those with zero analyzed reflectivity) due to the excessively small background hydrometeor values. In contrast, the 01:00 Z analysis (Fig. 11d) without preprocessing has a comparable error bias and SD to those with the preprocessing (Fig. 6d). These results indicate that the preprocessing step is mostly needed to address the bad background.

Figure 12a shows that the analyzed reflectivity in the melting layer has a reasonable fit to the observations even though it started from very small values of the background reflectivity. The analysis in the model space (Fig. 12b) is also similar to that with the preprocessing (Fig. 8b). However, the reflectivity coverage (>35 dBZ) in Fig. 12a is smaller than those in the observation and Exp_ref, which corresponds to the horizontally distributed points on the bottom of Fig. 11b. In contrast, the 01Z analysis without the preprocessing step (Fig. 12c, d) closely resembles that with the preprocessing (Figs. 7h and 8e) in terms of the radar reflectivity and hydrometeor mixing ratios, especially over the strong convective line (dashed black line in Fig. 12d). However, removing this preprocessing step results in a large spurious echo (marked by “A” in Fig. 12c) that is smaller in Fig. 7h. This implies that the preprocessing step will still be helpful for some “bad” locations (e.g., mismatched convective cells between the model background and observation) for a generally “good” background.

Figure 13 shows the 00:00 Z analysis reflectivity at 4 km a.g.l. with the horizontal correlation length scales of the background errors reduced by factors of 2 and 4. The spurious echoes weaken as the length scale decreases, especially for the spurious echoes marked by “A”. In addition, reducing the length scale improves the intensity analysis at certain locations (e.g., the convective cell marked by “B”; also see Fig. 7e, f). Note that the background error statistics used for these 3D-Var analyses were obtained from forecast samples over a month-long period and are likely not optimal for this particular squall line case. A better solution would be the use of the flow-dependent background error covariance, which will be investigated in the future using more advanced DA methods, such as 4D-Var and hybrid-3D/4DEnVar that are available in WRFDA.

The performance of the precipitation forecasts was quantitatively
evaluated using the stage IV dataset with the fractions skill score (FSS;
Roberts and Lean, 2008). Hourly precipitation forecasts between 02:00 and 05:00 Z
were evaluated because assimilating only the reflectivity is expected to
have an impact mostly on the short-term forecast. Similar to Schwartz et al. (2014), the aggregated FSS over the period from 02:00 to 05:00 Z is shown in Fig. 14 for the forecasts initialized at 00:00 and 01:00 Z and for different rainfall
thresholds. For the forecast from 00:00 Z (Fig. 15a), Exp_ref
obtained greater FSSs than those of noDA for thresholds greater than 5 mm h^{−1} with a radius of influence smaller than 40 km. With a larger
radius, this difference remains for the lighter rain (<20 mm h^{−1}) but disappears for the heavy rain (≥20 mm h^{−1}). Similar
behavior can be observed for the forecast at 01:00 Z (Fig. 15b) but with a more
positive impact from the radar DA for heavier rainfall and for a radius of
influence smaller than 50 km. Further examination (not shown) indicated that
the improvement in the moderate rain (>5 mm h^{−1}) prediction
was associated with the larger snow area in the analysis, so the light rain
missed by noDA was better captured in Exp_ref. This
examination also showed that the higher FSSs obtained by Exp_ref for the heavier rainfall were mostly associated with the smaller
displacement error.

6 Conclusions

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This study developed tangent linear and adjoint operators based on the J08 reflectivity operator and implemented them in WRFDA. This new operator can compute the reflectivity contributed by ice-phase species and is called RadarVar. RadarVar is effective at analyzing rainwater, snow, and graupel by directly assimilating US WSR-88D S-band radar reflectivity with WRFDA's 3D-Var. The analysis accuracy is somewhat sensitive to the numbers of outer loops and inner iterations. The results indicated that two to three outer loops with 50–100 iterations in each loop are needed to obtain a sufficiently accurate analysis. Two problems of RadarVar were found in our test. One issue is the analysis failures at locations with observed radar echoes but with zero or excessively small model background values of the hydrometeors. This issue can be partially resolved using a preprocessing step with radar-retrieved hydrometeors to improve the “bad” background before the analysis. Another issue is the spurious radar echoes (i.e., precipitation) in the analysis caused by the spatial correlations in the background error covariance. These can be reduced by decreasing the correlation length scales. In addition, the short-term (2–5 h) precipitation forecast is improved by the direct reflectivity DA even though the inexpensive univariate 3D-Var technique is used in this first attempt of applying RadarVar.

A more thorough evaluation of reflectivity DA with RadarVar will be examined in a future study using a more advanced hybrid ensemble–variational DA technique, which allows flow-dependent background errors with multivariate correlations and is expected to further reduce the aforementioned deficiencies. Moreover, RadarVar will be extended to include the computation of polarimetric quantities to better determine the phases of the hydrometeors, especially in the melting layers.

Code and data availability

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Code and data availability.

The RadarVar v1.0 operator is integrated into the community WRFDA software and will be publicly available in a future release. The code of RadarVar v1.0 and the scripts for running experiments in this study can be obtained at https://github.com/children1985/WRFDA_gmdd (Wang, 2019). The GFS data are available at https://www.ncdc.noaa.gov/data-access/model-data/model-datasets/global-forcast-system-gfs (National centers for environmental information, 2019a) and the radar data can be downloaded at https://www.ncdc.noaa.gov/nexradinv/ (National centers for environmental information, 2019b).

Appendix A

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This section provides details about the reorganization of all of the terms
in the brackets in Eq. (11) in terms of the *f*_{wx} power. For convenience,
the expressions in these brackets are represented by *G*(*f*_{wx}).

Applying Eq. (16) to the brackets in Eq. (11) results in

$$\begin{array}{}\text{(A1)}& \begin{array}{rl}G\left({f}_{\mathrm{w}x}\right)=& {\mathit{\epsilon}}_{x}^{\mathrm{2}}\left[A\right(\sum _{k=\mathrm{0}}^{n}{P}_{\mathrm{w}x\mathrm{a}k}{f}_{\mathrm{w}x}^{k}{)}^{\mathrm{2}}+B(\sum _{k=\mathrm{0}}^{n}{P}_{\mathrm{w}x\mathrm{b}k}{f}_{\mathrm{w}x}^{k}{)}^{\mathrm{2}}\\ & +\mathrm{2}C\left(\sum _{k=\mathrm{0}}^{n}{P}_{\mathrm{w}x\mathrm{a}k}{f}_{\mathrm{w}x}^{k}\right)\left(\sum _{k=\mathrm{0}}^{n}{P}_{\mathrm{w}x\mathrm{b}k}{f}_{\mathrm{w}x}^{k}\right)].\end{array}\end{array}$$

Expanding all of the terms of Eq. (A1) results in

$$\begin{array}{}\text{(A2)}& \begin{array}{rl}G\left({f}_{\mathrm{w}x}\right)=& {\mathit{\epsilon}}_{x}^{\mathrm{2}}\mathit{\left\{}A\sum _{i=\mathrm{0}}^{n}\right[{P}_{\mathrm{w}x\mathrm{a}i}\left(\sum _{j=\mathrm{0}}^{n}{P}_{\mathrm{w}x\mathrm{a}j}{f}_{\mathrm{w}x}^{i+j}\right)]\\ & +B\sum _{i=\mathrm{0}}^{n}\left[{P}_{\mathrm{w}x\mathrm{b}i}\right(\sum _{j=\mathrm{0}}^{n}{P}_{\mathrm{w}x\mathrm{b}j}{f}_{\mathrm{w}x}^{i+j}\left)\right]\\ & +\mathrm{2}C\sum _{i=\mathrm{0}}^{n}\left[{P}_{\mathrm{w}x\mathrm{a}i}\right(\sum _{j=\mathrm{0}}^{n}{P}_{\mathrm{w}x\mathrm{b}j}{f}_{\mathrm{w}x}^{i+j}\left)\right]\mathit{\}}\end{array}.\end{array}$$

Reorganizing the third term (omitting 2*C*) of Eq. (A2) in terms of the
*f*_{wx} power (*i*+*j*) results in

$$\begin{array}{}\text{(A3)}& \begin{array}{rl}& \sum _{i=\mathrm{0}}^{n}\left[{P}_{\mathrm{w}x\mathrm{a}i}\right(\sum _{j=\mathrm{0}}^{n}{P}_{\mathrm{w}x\mathrm{b}j}{f}_{\mathrm{w}x}^{i+j}\left)\right]={P}_{\mathrm{wxa}\mathrm{0}}{P}_{\mathrm{wxb}\mathrm{0}}{f}_{\mathrm{w}x}^{\mathrm{0}}\\ & +{P}_{\mathrm{wxa}\mathrm{0}}{P}_{\mathrm{wxb}\mathrm{1}}{f}_{\mathrm{w}x}^{\mathrm{1}}+{P}_{\mathrm{wxa}\mathrm{1}}{P}_{\mathrm{wxb}\mathrm{0}}{f}_{\mathrm{w}x}^{\mathrm{1}}\\ & \mathrm{\cdots}\\ & +{P}_{\mathrm{wxa}\mathrm{0}}{P}_{\mathrm{w}x\mathrm{b}n}{f}_{\mathrm{w}x}^{n}+{P}_{\mathrm{wxa}\mathrm{1}}{P}_{\mathrm{w}x\mathrm{b}(n-\mathrm{1})}{f}_{\mathrm{w}x}^{n}\\ & \phantom{\rule{1em}{0ex}}+\mathrm{\cdots}+{P}_{\mathrm{w}x\mathrm{a}n}{P}_{\mathrm{wxb}\mathrm{0}}{f}_{\mathrm{w}x}^{n}\\ & +{P}_{\mathrm{wxa}\mathrm{1}}{P}_{\mathrm{w}x\mathrm{b}n}{f}_{\mathrm{w}x}^{n+\mathrm{1}}+{P}_{\mathrm{wxa}\mathrm{2}}{P}_{\mathrm{w}x\mathrm{b}(n-\mathrm{1})}{f}_{\mathrm{w}x}^{n+\mathrm{1}}\\ & \phantom{\rule{1em}{0ex}}+\mathrm{\cdots}+{P}_{\mathrm{w}x\mathrm{a}n}{P}_{\mathrm{wxb}\mathrm{1}}{f}_{\mathrm{w}x}^{n+\mathrm{1}}\\ & \mathrm{\cdots}\\ & +{P}_{\mathrm{w}x\mathrm{a}(n-\mathrm{1})}{P}_{\mathrm{w}x\mathrm{b}n}{f}_{\mathrm{w}x}^{\mathrm{2}n-\mathrm{1}}+{P}_{\mathrm{w}x\mathrm{a}n}{P}_{\mathrm{w}x\mathrm{b}(n-\mathrm{1})}{f}_{\mathrm{w}x}^{\mathrm{2}n-\mathrm{1}}\\ & +{P}_{\mathrm{w}x\mathrm{a}n}{P}_{\mathrm{w}x\mathrm{b}n}{f}_{\mathrm{w}x}^{\mathrm{2}n}\\ & =\sum _{k=\mathrm{0}}^{n}\left[{f}_{\mathrm{w}x}^{k}\sum _{i=\mathrm{0}}^{k}{P}_{\mathrm{w}x\mathrm{a}}i{P}_{\mathrm{w}x\mathrm{b}(k-i)}\right]\\ & \phantom{\rule{1em}{0ex}}+\sum _{k=n+\mathrm{1}}^{\mathrm{2}n}\left[{f}_{\mathrm{w}x}^{k}\sum _{i=k-n}^{n}{P}_{\mathrm{w}x\mathrm{a}i}{P}_{\mathrm{w}x\mathrm{b}(k-i)}\right].\end{array}\end{array}$$

The sum functions in the square brackets on the right-hand side of Eq. (A3) correspond to the third expression of Eq. (20). Using the third expression of Eq. (20), the third term of Eq. (A2) is rewritten as follows:

$$\begin{array}{}\text{(A4)}& \begin{array}{rl}& \mathrm{2}C\sum _{i=\mathrm{0}}^{n}\left[{P}_{\mathrm{w}x\mathrm{a}i}\right(\sum _{j=\mathrm{0}}^{n}{P}_{\mathrm{w}x\mathrm{b}j}{f}_{\mathrm{w}x}^{i+j}\left)\right]\\ & \phantom{\rule{1em}{0ex}}=\mathrm{2}C\mathit{\left\{}\sum _{k=\mathrm{0}}^{n}\right[{f}_{\mathrm{w}x}^{k}\sum _{i=\mathrm{0}}^{k}{P}_{\mathrm{w}x\mathrm{a}i}{P}_{\mathrm{w}x\mathrm{b}}(k-i)]\\ & \phantom{\rule{1em}{0ex}}+\sum _{k=n+\mathrm{1}}^{\mathrm{2}n}\left[{f}_{\mathrm{w}x}^{k}\sum _{i=k-n}^{n}{P}_{\mathrm{w}x\mathrm{a}i}{P}_{\mathrm{w}x\mathrm{b}}\right(k-i\left)\right]\mathit{\}}\\ & \phantom{\rule{1em}{0ex}}=\mathrm{2}C\sum _{k=\mathrm{0}}^{\mathrm{2}n}{P}_{Cxk}{f}_{\mathrm{w}x}^{k},\end{array}\end{array}$$

where *P*_{Cxk} has the same meaning as in Eq. (20). Similarly, we can
rewrite the other two terms in Eq. (A2) as follows:

$$\begin{array}{}\text{(A5)}& \begin{array}{rl}& A\sum _{i=\mathrm{0}}^{n}\left[{P}_{\mathrm{w}x\mathrm{a}i}\right(\sum _{j=\mathrm{0}}^{n}{P}_{\mathrm{w}x\mathrm{a}j}{f}_{\mathrm{w}x}^{i+j}\left)\right]=\\ & \phantom{\rule{1em}{0ex}}A\mathit{\left\{}\sum _{k=\mathrm{0}}^{n}\right[{f}_{\mathrm{w}x}^{k}\sum _{i=\mathrm{0}}^{k}{P}_{\mathrm{w}x\mathrm{a}i}{P}_{\mathrm{w}x\mathrm{a}(k-i)}]\\ & \phantom{\rule{1em}{0ex}}+\sum _{k=n+\mathrm{1}}^{\mathrm{2}n}\left[{f}_{\mathrm{w}x}^{k}\sum _{i=k-n}^{n}{P}_{\mathrm{w}x\mathrm{a}i}{P}_{\mathrm{w}x\mathrm{a}(k-i)}\right]\mathit{\}}\\ & \phantom{\rule{1em}{0ex}}=A\sum _{k=\mathrm{0}}^{\mathrm{2}n}{P}_{Axk}{f}_{\mathrm{w}x}^{k}\\ & B\sum _{i=\mathrm{0}}^{n}\left[{P}_{\mathrm{w}x\mathrm{b}i}\right(\sum _{j=\mathrm{0}}^{n}{P}_{\mathrm{w}x\mathrm{b}j}{f}_{\mathrm{w}x}^{i+j}\left)\right]=\\ & \phantom{\rule{1em}{0ex}}B\mathit{\left\{}\sum _{k=\mathrm{0}}^{n}\right[{f}_{\mathrm{w}x}^{k}\sum _{i=\mathrm{0}}^{k}{P}_{\mathrm{w}x\mathrm{b}i}{P}_{\mathrm{w}x\mathrm{b}(k-i)}]\\ & \phantom{\rule{1em}{0ex}}+\sum _{k=n+\mathrm{1}}^{\mathrm{2}n}\left[{f}_{\mathrm{w}x}^{k}\sum _{i=k-n}^{n}{P}_{\mathrm{w}x\mathrm{b}i}{P}_{\mathrm{w}x\mathrm{b}(k-i)}\right]\mathit{\}}=\\ & \phantom{\rule{1em}{0ex}}B\sum _{k=\mathrm{0}}^{\mathrm{2}n}{P}_{Bxk}{f}_{\mathrm{w}x}^{k}.\end{array}\end{array}$$

Because these three expressions (Eqs. A4 and A5) contain the same sum
function with respect to *k* from 0 to 2*n*, Eq. (A2) can be rewritten as follows:

$$\begin{array}{}\text{(A6)}& \begin{array}{rl}& G\left({f}_{\mathrm{w}x}\right)={\mathit{\epsilon}}_{x}^{\mathrm{2}}(A\sum _{k=\mathrm{0}}^{\mathrm{2}n}{P}_{Axk}{f}_{\mathrm{w}x}^{k}+B\sum _{k=\mathrm{0}}^{\mathrm{2}n}{P}_{Bxk}{f}_{\mathrm{w}x}^{k}\\ & \phantom{\rule{1em}{0ex}}+\mathrm{2}C\sum _{k=\mathrm{0}}^{\mathrm{2}n}{P}_{Cxk}{f}_{\mathrm{w}x}^{k})\\ & ={\mathit{\epsilon}}_{x}^{\mathrm{2}}\sum _{k=\mathrm{0}}^{\mathrm{2}n}(A{P}_{Axk}{f}_{\mathrm{w}x}^{k}+B{P}_{Bxk}{f}_{\mathrm{w}x}^{k}+\mathrm{2}C{P}_{Cxk}{f}_{\mathrm{w}x}^{k})\\ & ={\mathit{\epsilon}}_{x}^{\mathrm{2}}\sum _{k=\mathrm{0}}^{\mathrm{2}n}(A{P}_{Axk}+B{P}_{Bxk}+\mathrm{2}C{P}_{Cxk}){f}_{\mathrm{w}x}^{k}\\ & ={\mathit{\epsilon}}_{x}^{\mathrm{2}}\sum _{k=\mathrm{0}}^{\mathrm{2}n}{P}_{xk}{f}_{\mathrm{w}x}^{k}.\end{array}\end{array}$$

Author contributions

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Author contributions.

SW performed the coding and designed the data assimilation experiments. ZL supervised this study. All authors contributed to the writing of the paper.

Acknowledgements

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Acknowledgements.

This work was jointly sponsored by the National Key Research and Development Program of China (2017YFC1502103), the National Natural Science Foundation of China (41505089, 41875129, 41505090, 41430427, and 41805070), the Startup Foundation for Introducing Talent of NUIST (2014R007), and National Key Research and Development Program of China (2018YFC1506404). NCAR is sponsored by the US National Science Foundation.

Financial support

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Financial support.

This work was jointly sponsored by the National Key Research and Development Program of China (grant no. 2017YFC1502103) and the National Natural Science Foundation of China (grant nos. 41875129, 41430427, and 41805070). NCAR is sponsored by the US National Science Foundation.

Review statement

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Review statement.

This paper was edited by Richard Neale and reviewed by Juanzhen Sun and one anonymous referee.

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Short summary

A reflectivity operator was developed for directly assimilating radar reflectivity involving contributions from ice species with the variational data assimilation method. Its current version was implemented in WRFDA 3.9.1. This operator allows for not only the dry snow/graupel but also the wet species so that it can effectively obtain the rainwater, snow, and graupel analysis which improved the short-term precipitation forecasts compared to those of the experiment without DA.

A reflectivity operator was developed for directly assimilating radar reflectivity involving...

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