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Article

Polarimetric Radar Signatures and Performance of Various Radar Rainfall Estimators during an Extreme Precipitation Event over the Thousand-Island Lake Area in Eastern China

1
Hangzhou Meteorological Bureau, Hangzhou 310051, China
2
Zhejiang Institute of Meteorological Sciences, Hangzhou 321000, China
3
NOAA/Earth System Research Laboratory, Boulder, CO 80305, USA
4
Cooperative Institute for Research in the Atmosphere, Fort Collins, CO 80523, USA
5
Plateau Atmosphere and Environment Key Laboratory of Sichuan Province, School of Atmospheric Sciences, Chengdu University of Information Technology, Chengdu 610225, China
*
Author to whom correspondence should be addressed.
Remote Sens. 2019, 11(20), 2335; https://doi.org/10.3390/rs11202335
Submission received: 19 August 2019 / Revised: 4 October 2019 / Accepted: 6 October 2019 / Published: 9 October 2019
(This article belongs to the Special Issue Precipitation and Water Cycle Measurements Using Remote Sensing)

Abstract

:
Polarimetric radar provides more choices and advantages for quantitative precipitation estimation (QPE) than single-polarization radar. Utilizing the C-band polarimetric radar in Hangzhou, China, six radar QPE estimators based on the horizontal reflectivity (ZH), specific attenuation (AH), specific differential phase (KDP), and double parameters that further integrate the differential reflectivity (ZDR), namely, R(ZH, ZDR), R(KDP, ZDR), and R(AH, ZDR), are investigated for an extreme precipitation event that occurred in Eastern China on 1 June 2016. These radar QPE estimators are respectively evaluated and compared with a local rain gauge network and drop size distribution data observed by two disdrometers. The results show that (i) although R(AH, ZDR) underestimates in the light rain scenario, it performs the best among all radar QPE estimators according to the normalized mean error; (ii) the optimal radar rainfall relationship and consistency between radar measurements aloft and their surface counterparts are both required to obtain accurate rainfall estimates close to the ground. The contamination from melting layer on AH and KDP can make R(AH), R(AH, ZDR), R(KDP), and R(KDP, ZDR) less effective than R(ZH) and R(ZH,ZDR). Instead, adjustments of the α coefficient can partly reduce such impact and hence render a superior AH–based rainfall estimator; (iii) each radar QPE estimator may outperform others during some time intervals featured by particular rainfall characteristics, but they all tend to underestimate rainfall if radar fails to capture the rapid development of rainstorms.

Graphical Abstract

1. Introduction

Polarimetric radar measurements, including horizontal reflectivity (ZH), radial velocity (Vr), differential reflectivity (ZDR), the copolar correlation coefficient (ρHV), the differential propagation phase (ΦDP), and the specific differential phase (KDP), have the potential to be used in the areas of severe weather/tornado warnings, cloud microphysics, and rainfall estimation/forecasting, which are all important modern meteorological and hydrological applications [1,2,3,4,5,6,7,8,9]. Recently, all the operational weather radars in the U.S. (i.e., Next-Generation Radar—NEXRAD), UK, and Ireland have been upgraded with dual-polarization capability [10], which can transmit/receive horizontal and vertical radar waves simultaneously, and weather radars in many other European countries are almost at full dual-polarization capability. Some weather radar sites in China have also been upgraded to dual-polarization capability to replace the original single-polarization weather radars. In addition, some experimental or operational X-band polarimetric radar networks have been deployed near metropolitan urban areas to monitor small-scale severe weather systems [2,3,4,5], which makes the synthesis of polarimetric radars for severe weather diagnosis, warning, and decision-making operations more important than ever. Among these operations, radar quantitative precipitation estimation (QPE) plays an indispensable role, and it is a challenging task to obtain accurate structure of the rain rate (R) field [9,11] for flood or mudslide warnings in mountainous areas and waterlogging prevention, especially in densely populated urban areas [3,4,5].
Conventional single-polarization radar QPE procedures use ZH as the main source for rainfall field retrieval. For example, the national multi-radar quantitative precipitation estimation system in the United States and Canada [12] is based on ZH, which has been recently refined by incorporating different ZR relationships that vary based on climatology. Since single-polarization weather radar is still prevalent in China, and the gauge network in Eastern China is nearly ten times denser than that in the U.S., radar-gauge fitted Z–R relationships have also been incrementally improved recently, mainly by utilizing the gauge-feedback mechanism [13]. However, on one hand, ZH is inevitably affected by data quality issues, such as miscalibration, attenuation, and partial beam blockage (PBB), and wet radome effects, etc. These negative effects can be significant, especially for X- and C-band radar, and are hard to completely mitigate for single-polarization radar [14,15,16]. On the other hand, the Z–R relationships based on the feedback mechanism assume the gauge measurements to be the “truth”. Radar-estimated rainfall has to approximate the gauge measurements, and any uncertainty in gauge measurements may degrade the practical performance of fitted ZR relationships.
With more and more weather radar systems being updated with dual-polarization capability, many researchers have been focusing on improving the performances of radar QPE algorithms based on independent or composite utilization of polarimetric variables, which provides a complementary alternative to conventional radar QPE algorithms. Among these, KDP is preferable for many researchers and there are at least three reasons why KDP is more attractive for rainfall estimation. First, KDP is proportional to a moment of the particle size distribution (PSD) closer to that of the rain rate. The rain rate is proportional to approximately the 3.67th moment of the PSD, while KDP is proportional to the ~4.24th moment [17] and ZH is proportional to the ~6th moment. Therefore, KDP is much less sensitive to changes in the concentration of the largest drops that do not contribute much to the total rainfall. In addition, KDP is immune to isotropic scatterers and is frequently assumed to be near-zero for tumbling hail. Last, KDP is characterized by immunity to miscalibration, attenuation, and PBB and wet radome effects; conversely, these issues may degrade the quality of ZH measurements [18].
Considering that raindrop shape can be indirectly deduced from ZDR, the double-parameter radar QPE algorithm based on ZH and ZDR, namely, R(ZH, ZDR), is a better choice than R(ZH), assuming that ZH and ZDR are both well calibrated and attenuation-corrected [1,18]. For a similar reason, R(KDP, ZDR) was established as another double-parameter radar QPE estimator through combining ZDR with KDP; however, not all reports have concluded that R(KDP, ZDR) can outperform R(KDP), especially at X-band [15,19,20]. Triple-parameter radar QPE estimators, such as R(ZH, ZDR, KDP), have also been proposed at X-band [21], which can further incorporate the altitude of radar measurements to account for the drop fall velocity changes caused by changes in the density of ambient air [22]. However, the triple-parameter radar QPE estimator is less widely used, because an increased number of radar variables may introduce more uncertainty. The specific attenuation (AH) is insensitivive to raindrop size distribution (DSD) variability, and recent investigations show that R(AH) performs better than R(ZH) at X-band and S-band [23,24,25]. In addition, AH can also be joined with ZDR to form a double-parameter estimator, denoted by R(AH, ZDR), which was declared to be less affected by the biases due to the assumed raindrop axial ratio [26,27] at the X-band, but this algorithm has never been examined at the C-band radar.
The novel contributions of this paper are as follows: (i) We develop and test a new R(AH,ZDR) estimator for a C-band polarimetric (CPOL) radar for the first time, which utilizes the improved self-consistent attenuation correction method (i.e., the ZPHI approach) proposed by Bringi et al. [28] through the incorporation of more microphysical constraints in the correction process of ZH and ZDR [29,30]. (ii) We also intercompare different radar rainfall estimators to address their advantages and disadvantages, utilizing the first high-quality and high-resolution (i.e., 125 m range resolution and 0.46 deg azimuthal resolution) CPOL radar deployed in Hangzhou, China and rainfall recordings of the highly dense gauge network around Hangzhou. (iii) We develop optimal radar QPE parameters for monsoon rainfall using the regional DSD dataset during a serious waterlogging event around the Thousand-Island Lake (TIL) area in Eastern China. The rest of this manuscript is organized as follows: Section 2 introduces the dataset used in this study and the data processing methods involved; Section 3 examines the comparison results of different radar QPE algorithms; and Section 4 summarizes and concludes this study.

2. Study Domain, Dataset, and Rainfall Methodology

2.1. Study Area and Hardware Configuration

The CPOL radar in Hangzhou is situated on a high mountain top (1512 m above sea level) around the complex mountainous area in eastern China, as depicted in Figure 1a. The TIL area is located within 100 km of the CPOL radar site with the altitude of radar beams 1.6–2.1 km above-ground-level (and no beam blockage over the TIL area). It is an important artificial lake which covers an area of 580 km2 under normal water levels, and it was constructed mainly for the Xin-An River hydropower station. The study domain shown in the rectangle in Figure 1a covers the southern area of Chun An (CA) town and the western area of Jiang De (JD) town of Hangzhou, and the mountainous terrain that surrounds the north and south areas of TIL. In addition, TIL is situated just at the upper stream of the Qiantang River, along which are densely populated areas; therefore, hydrologic monitoring around the TIL area is very important, especially in the summer monsoon season.
The unique topography around the TIL area makes the CPOL radar an indispensable seamless surveillance device for severe rainfall monitoring and nowcasting operations, because the other radar sites are either far from this area or seriously blocked by the mountainous terrain. The CPOL radar is mainly configured with simultaneous horizontal and vertical polarization modes for its routine daily operations. The elevation angles of its volume coverage pattern (VCP) have been set as 0.0°, 0.5°, 1.5°, 2.5°, 3.5°, 4.5°, 6.0°, 7.5°, and 9.0° since September 2015 and one VCP scan can be finished in about six minutes. The azimuthal radial resolution of three lowest three VCP sweeps are configured as 0.46°; the others are configured as 0.95°. In addition, the range gate resolution of the CPOL radar is configured as 125 m at all elevations. The measured ΨDP, ZH, ZDR, ρHV, and radial velocity are all archived into a “.bz2” package in the radar data acquisition (RDA) system for posterior product generation.
Two second-generation Particle Size and Velocity (Parsivel2) disdrometers, which can provide simultaneous measurements of the particle size and falling velocity information of raindrops with a sampling resolution of one minute, were deployed at the national meteorological stations at CA and JD towns, respectively (see the bold “+” in Figure 1a,b). They are maintained routinely to ensure the data quality of DSD measurements, which are important surface observation sources that are used to simulate dual-polarization radar measurements and to investigate regional rainfall characteristics. In addition, 786 tipping-bucket gauge stations (see small “+” in Figure 1b) were deployed within range of 100 km from the CPOL radar. The temporal resolution of the rain gauges is also specified as one minute. The gauge observations without any interruptions are used for the verification of radar rainfall estimates, and if any ratios between six radar hourly estimates and gauge hourly measurements exceed 5, the gauge measurements are suspected to be false reports and will be abandoned and not used for the validation aim. This simple quality control procedure can eliminate a small portion of significantly biased gauge measurements but keep most large rainfall recordings.
A severe rainfall event on 01 June 2016 caused a large area of JD town to suffer from a serious waterlogging disaster. Several people were not evacuated immediately and were trapped in the disaster zone. The meteorological stations situated in the severe rainfall center area, including Jia Ziling (JZL), Shi Lin (SL), Qian Daohu (QDH), Xi Hua (XH), Shou Chang (SC), Geng Lou (GL), Zhi Yan (ZY), and Gan Xi (GX), are all marked with small “+” symbols in Figure 1c. The pictures in Figure 1c depict the waterlogging scenes that show a large area of submerged farmland around this area and the local emergency managers were working near GL station aiming to rescue the trapped people in the village near GL station.

2.2. Radar Data Processing

Radar quality control procedures imposed on polarimetric radar variables were successively implemented. Several key issues within the procedure include the following processing steps:
(i) Ground clutter (GC) mitigation.
The clutter mitigation decision (CMD) algorithm proposed by Hubbert et al. [31] was utilized and integrated into the radar data acquisition (RDA) software. The CMD algorithm incorporates clutter phase alignment that was extracted from the radar I and Q (in-phase and quadrature-phase) data, the spatial texture of ZH, the spin-change of ZH, which was defined by Steiner and Smith (2002) [32] to measure how often the reflectivity gradient changes sign along the radar radial, and the standard deviation of ZDR and ΨDP as the input parameters of a fuzzy logic scheme to identify the GC signals. Radar measurements were instantaneously filtered in the scanning process to eliminate the GC signal contamination. The statistics of the ZH measurements before and after the clutter filtering during June 2016 at an elevation 0° show that the maximum number (Nmax) of pixels with ZH > 0 dBZ in the range of 180 km of the CPOL radar was 6981. The observation number (Nobs) of each pixel was normalized by dividing Nmax to derive the relative frequency (Freq.%) of these pixels, and the results are depicted in Figure 2. The GC pixels with a high probability of occurrence in Figure 2a are effectively eliminated in Figure 2b. In addition, the pixels in Figure 2b are still spatially continuous and smooth, which indicates the effectiveness of the CMD algorithm.
(ii) ΨDP Processing.
The spike signal, which refers to the large and sharp increase of ΨDP along the range profile, was first suppressed by using the average of its two aligned range gates without any large changes with respect to the aligned four range gates. Then, a nine-gate average operation was used to smooth the ΨDP range profile. According to the monotonous increasing characteristics of the ΨDP range profile, a ΨDP dealiasing procedure was then executed if the measured ΨDP exceeded 360°, and the standard deviation of ΨDP derived from nine consecutive range gates was used in this process [33]. The iterative filtering method [34,35] was used to filter the backscatter differential phase and to obtain a high quality ΦDP ( Φ DP filtered ) range profile. Finally, the initial phase of ΦDP was determined using the linear regression method and removed from the ΦDP range profile. The ΦDP range profile was then utilized to estimate KDP through the linear fitting approach [33] and the posterior attenuation correction of ZH.
(iii) Calibration and attenuation correction.
For practical implementation, the ZPHI method proposed by Bringi et al. [28], which is demonstrated in Equations (1a)–(1f), was imposed with three constraints: A non-negative constraint on AH estimation, a ρHV constraint on the range gates partitioning process, and a convergence constraint to check whether the difference between Φ DP and reconstructed Φ DP rec in Equation (1e) of every range interval was minimized [29]. It was implemented in every partitioned range interval [r0, rm] along each radial profile to estimate the specific attenuation (AH) according to Equations (1a)–(1d) by assuming a constant parameter b (0.78) [28]. Then, the optimal parameters of αopt were searched for in [0.03, 0.18] to minimize the difference between Φ DP and the reconstructed Φ DP rec in Equation (1e) in each partitioned range interval. Finally, the measured ZH ( Z H M ) was corrected by Equation (1f) as Z H C utilizing the optimally estimated AH. Z H C and AH were respectively used in R(ZH) and R(AH).
A H ( r ) = [ Z H M ] b [ 10 0.1 b α Δ Φ ( r 0 , r m ) 1 ] I ( r 0 , r m ) + [ 10 0.1 b α Δ Φ ( r 0 , r m ) 1 ] I ( r , r m )
Δ Φ DP ( r 0 , r m ) = Φ DP ( r m ) Φ DP ( r 0 )
I ( r 0 , r m ) = 0.46 b r 0 r m [ Z H M ( r ) ] b d r
I ( r , r m ) = 0.46 b r r m [ Z H M ( r ) ] b d r
Φ DP rec ( r 0 , r m ) = r 0 r m A H ( s , α ) α d s
Z H C ( r ) = Z H M ( r ) + 2 0 r A H ( s , α ) d s .
(v) Calibration and attenuation correction of ZDR.
The “birdbath” scan method is routinely carried out for ZDR calibration before the upcoming monsoon season, which is usually performed through vertically pointing observations (elevation of 90°) in a full azimuthal rotation [1]. The ZDR offset can be obtained with respect to the nearly zero values of ZDR in the light rain scenarios, and then this offset is fed back to the RDA system to make sure there is a low ZDR bias. Moreover, an event-derived exponential ZDRZH relationship (see the black line on Figure 3a) is shown by Equation (2a). This was derived through the standard weighted least-squares nonlinear fitting method based on the DSD dataset collected during the period 0000–2359 UTC on 1 June 2016. Therein, ZH, ZDR, KDP, and AH were simulated by the T-matrix method, assuming the raindrop aspect ratio presented in Brandes et al. [36], at a temperature of 20 °C.
The differential attenuation factor (ADP) in Equation (2b) was derived according to the optimal β, which was obtained through minimizing the differences between the estimated ZDR in Equation (2a) and the ZDR guessed by the potential ADP in Equations (2b) and (2c) along the whole radial range profile. Finally, the measured ZDR ( Z DR M ) along the range profile was corrected by Equation (2c) as Z DR C , which was then integrated with ZH, KDP, and AH for rainfall estimation.
Z ^ DR ( r ) = 1.377 × 10 4 Z H C ( r ) 2.5005
A DP ( r ; β ) = β α opt A H ( r ; α opt )
Z DR C ( r ; β ) = Z DR M ( r ) + 2 0 r A DP ( s , β ) d s

2.3. The Polarimetric Radar Rainfall Estimators

Utilizing the DSD dataset collected during the period 0000–2359 UTC on 1 June 2016 at CA and JD, the event-derived radar rainfall rate relationships based on R(ZH), R(KDP), R(AH), R(ZH, ZDR), R(KDP, ZDR), and R(AH, ZDR) were established using the T-matrix-derived polarimetric variables for the CPOL radar rainfall applications as follows:
R ( Z H ) = 0.0457 × Z H 0.633
R ( Z H , Z DR ) = 0.0039 × Z H 0.916 Z DR 1.604
R ( K DP ) = 23.598 × K DP 0.855
R ( K DP , Z DR ) = 29.436 × K DP 0.896 Z DR 0.573
R ( A H ) = 203.5894 × A H 0.755
R ( A H , Z DR ) = 323.1317 × A H 0.945 Z DR 1.922
Both ZH and ZDR were on a linear scale. These radar rainfall rate relationships were derived using the standard weighted least-squares nonlinear fitting method with the results depicted Figure 4. The single averaged R(ZH) and R(KDP) relationships were utilized rather than the combined radar QPE estimators, with the aim to see the relative superiority of combined polarimetric radar variables. The pixel-to-pixel linear average accumulation scheme was then used to retrieve radar hourly accumulation field for these radar QPE estimators, and they were then evaluated independently by hourly gauge measurements to see their real performances in the severe rainfall event around the TIL area. Rainfall rates estimated from the polarimetric variables calculated from observed DSDs at CA and JD stations were also accumulated hourly to check the quality of the radar-estimated and gauge-measured hourly rainfall series.

3. Results and Discussion

3.1. Description of Synoptic Characteristics

According to the wind directions (bold arrows) depicted in Figure 5a, there was a quasi-stationary front, and sustained moisture convergence led to persistent convection. The ΦDP measurements, which passed through the convective rainstorms in many radial directions, exceeded 100° (Figure 5b), and they were directly responsible for the large KDP values shown in Figure 5e. According to posterior analysis, these rainstorms had high concentrations of moderately-sized raindrops, and they were intrinsically related to the sustained moisture convergence along the quasi-stationary front. Consequently, the rainstorms showed a northwestern distribution along this front, supported by the large-scale environment.
For the posterior analysis, the consistency between ZH, ZDR, and KDP shown in Figure 5c–e was first verified through the scattergram in Figure 6 to check their quality. The T-matrix-derived ZH, ZDR, and KDP dataset depicted in Figure 3 was also overlaid on the scattergrams shown in Figure 6 (black dots) for comparison. It can be seen that the scattergram of radar-observed ZDR vs. ZH presented in Figure 6a agrees well with the T-matrix-derived ZDRZH distributions shown in Figure 3a, and ZDR presented an obvious exponentially increasing tendency as ZH increased, which coincides with the scattering characteristics of the oblate liquid raindrops. The scattergram of radar-observed KDP and ZH derived from Figure 5c,e is also consistent with the T-matrix-derived counterparts shown in Figure 3b, and the large ZH measurements agree well with the large KDP estimates. The consistency between ZH, ZDR, and KDP demonstrates that the attenuation correction and calibration of ZH and ZDR were good. However, radar-observed AH was not completely consistent with ZH, as depicted in Figure 6c, and the black T-matrix-derived dots of AH vs. ZH just passed through the center area of radar-observed distribution of AH vs. ZH. Some radar-observed AH values were larger than the T-matrix-derived dots of AH, while others were smaller, particularly when ZH exceeded 40 dBZ. AH related to KDP in a linear form as AH = αKDP with α ranging from 0.03 to 0.18, which can be seen from the ratios between AH and KDP shown in Figure 6d. That is, the combination of AH and α together was consistent with attenuation-corrected ZH measurements. In addition, the range of AH was relatively small, and the high altitudes (1.6–2.1 km) of the CPOL radar measurements by radar-observed AH may be very different from their surface counterparts.
Some microphysical information about the rainstorms can accordingly be deduced. Assuming the gamma model and neglecting the possible uncertainty induced by parameter u, the polynomial relationship between the median volume diameter (D0) and ZDR and the exponential relationship between the liquid water content (LWC, g·m−3) and KDP, which were fitted using the localized DSD dataset during the monsoon season of Hangzhou [30] and the normalized concentration of raindrops Nw (mm−1·m−3) presented in Ryzhkov et al. (2014) and Testud et al. (2001) [23,37], respectively, can be represented as
D 0 = 0.9655 × Z DR 3 2.3309 × Z DR 2 + 2.3627 × Z DR + 0.4252
LWC = 1.0397 × K DP 0.9718
N w = 4 4 π ρ w LWC D m 4
where ρw is the water density (1 g·cm−3 at 4℃), and Dm (mm) stands for the mean volume diameter of the DSD. It is clearly seen that only a small part of ZDR measurements in Figure 5d and Figure 6a exceeded 2 dB along the area with positive and negative Vr pairs, which was mainly related to the convective updraft area. Instead, most ZDR measurements of these rainstorms were featured by ZH > 20 dBZ and 0.25 dB ≤ ZDR ≤ 2dB, within which the D0 of most DSD rarely exceeded 2 mm according to Equation (4), and moderately-sized raindrops with 1 mm ≤ D0 ≤ 2 mm may be the dominant hydrometeors of these rainstorms. However, the southwestern convergence area shown in Figure 5c was featured by KDP > 1 deg·km−1 with a maximum of 8 deg·km−1, which can also be seen in Figure 6b. Therefore, the LWC within the rainstorm was higher than 1 g·m−3 and it increased linearly if KDP exceeded 1 deg·km−1. The value of Dm in Equation (6) was also expected to be less than 2 mm, and Nw was at least larger than 5000 mm1m3 if KDP became larger than 1 deg·km−1, which implied that a high concentration of moderately-sized raindrops within the convective rainstorms was the microphysical reason for this waterlogging disaster. Furthermore, a similar rainfall pattern persisted for more than 3 h over the study area. The radar retrieved rainfall field was indispensable for the decision-making related to this disaster warning.

3.2. Evaluation Metrics

By utilizing the radar rainfall rate relationships in Equations (3a)–(3f), three single-parameter and three double-parameter radar rainfall fields were retrieved, respectively. The radar hourly estimated rainfall fields within 100 km from the CPOL radar were then compared with hourly gauge rainfall measurements. In addition, rainfall rates calculated from DSD data at CA and JD stations were also aggregated into hourly rainfall measurements for comparison. Three simple statistical scores, including the normalized mean error (ENM), root-mean-square error (ERMS), and correlation coefficient (ECC), were used to evaluate these radar rainfall fields. They were defined as
E NM = i = 1 n ( r i g i ) i = 1 n g i × 100 %
E RMS = 1 n i = 1 n ( r i g i ) 2
E CC = i = 1 n ( r i r ¯ ) ( g i g ¯ ) i = 1 n ( r i r ¯ ) 2 i = 1 n ( g i g ¯ ) 2
where ri and gi are radar-estimated and gauge-observed hourly rainfall accumulations, and r ¯ and g ¯ stand for their average values. Smaller |ENM| and ERMS scores and larger ECC scores are associated with superior radar QPE performance.

3.3. Comparison of Different Radar QPE Approaches

By utilizing the rainfall rate relationships in Equations (3a)–(3f), six radar-based 3-h rainfall accumulation fields at 0500 UTC on 1 June 2016 were obtained, as shown in Figure 7. At the same time, the scatter between radar 3-h estimates and gauge 3-h observations are also depicted in Figure 8 to show the relative differences between radar estimates and gauge measurements.
Although the shape of these rainfall fields of R(ZH) in Figure 7a is similar to that of the others, the score of R(ZH) in Table 1 shows that R(ZH) seriously underestimated the rainfall center field. This phenomenon can be clearly seen in Figure 8a, particularly when the gauge 3-h rainfall measurement exceeded 40 mm, and the negative deviation of radar estimates from gauge measurements was more serious with higher rainfall amounts. It can also be seen from Figure 4a that more scatter dots were found above the black curve when ZH exceeded 50 dBZ, which implies the potential underestimation of R(ZH) in the rainfall center with higher ZH measurements. Such uncertainties may result from the absence of separate size information (such as D0 and Dm) and the concentration information (Nw) of raindrops within the rainstorms, because ZH was a composite radar moment of these two factors.
Compared with R(ZH), the scores of R(ZH, ZDR) in Table 1 all improved. Moreover, the radar–gauge data pairs in Figure 8b are more uniformly scattered along the diagonal line (i.e., y = x) than those in Figure 8a. This result indicates that combining the potential raindrop shape information through ZDR was more effective than the single ZH utilization, as it mitigated this deficiency of ZH. However, R(ZH, ZDR) is still underestimated since the negative ENM values and more scatter dots distributed below the diagonal line can be observed in Figure 8b.
It is hard to say R(KDP) performed better than R(ZH) from the ERMS comparison in Table 1; however, the scattergram of of R(ZH) in Figure 8a was more distributed below the diagonal line in Figure 8a than the scattergram of R(KDP) in Figure 8c. The latter was more uniformly distributed along the diagnoal line, espically in the range of 0–75 mm, where the scattergram of R(AH) was more distributed above the diagonal line in Figure 8e. Based on this, R(KDP) performed best among single-parameter retrievals. Except for the immunity of KDP to attenuation and wet radome effects, the superiority of R(KDP) to the other two single-parameter radar estimates can be attributed to the fact that KDP was more directly and cohesively associated with LWC [38], which is represented by the aforementioned Equation (5). However, there are more scatter dots distributed above the diagonal line in Figure 8c when the 3-h gauge measurements exceeded 75 mm, which apparently accounts for the overestimation of R(KDP) in the rainfall center area.
R(KDP, ZDR) further integrated the raindrop shape information through ZDR; however, the scores of R(KDP, ZDR) were actually inferior to those of R(KDP) shown in Table 1, and the overestimation effect seemed more serious in Figure 8d than that in Figure 8c. This indicates that additional incorporation of ZDR is not effective for R(KDP, ZDR), at least in this event, and that the basic equational form of ZDR and KDP in R(KDP, ZDR) may account for this phenomenon. It was noticed that R(KDP, ZDR) in Schneebeli and Berne [20] assumed the exponent of KDP to be a constant of 1 and just fitted the parameters related to ZDR, which may better utilize the nearly linear relation between KDP and LWC according to Equation (5). In addition, it is better to make the ZDR-related component of R(KDP, ZDR) play a micro-adjusting role if the KDP-related component of R(KDP, ZDR) can perform at least as well as R(KDP). Actually, KDP contains shape information in a less straightforward way than ZDR, since oblateness is always required when radar wave passes through a rainstorm and a spherical particle would have KDP = 0 regardless of its size, this partly explains why the addition of ZDR cannot significantly improve R(KDP).
R(AH) performed worse than R(KDP) based on all evaluation scores. Although AH was also not sensitive to the negative effects on ZH (see Section 1), the calculation of AH in Equation (1a) includes ΦDP and the original radar measured ZH, and AH was less associated with rainfall rate than KDP. R(AH) was also inferior to R(ZH) according to the ERMS and ECC scores; however, according to the ENM scores shown in Table 1 and the scattergrams shown in Figure 4a,c, R(AH) tended to overestimate, especially at higher rainfall rates; in contrast, R(ZH) tended to underestimate in similar patterns. For convenience, radar-observed KDP vs. ZH and AH vs. ZH, shown in Figure 6b,c, respectively, can be compared to see the differences between KDP and AH. For the same ZH values, radar-observed KDP vs. ZH shows less difference (about ±0.5 deg·km-1) from T-matrix-derived KDP vs. ZH in Figure 6b. In contrast, radar-observed AH vs. ZH suffers from a relatively wider distribution difference (about ±0.3 dB·km-1 and more positive deviation with ZH > 40 dBZ) from T-matrix-derived AH vs. ZH in Figure 6c. That is, radar-observed AH seemed to be overestimated more than KDP in some radar beams. An unobserved microphysical transition may occur during the falling process of the hydrometeors from the altitude of 1.6–2 km to the surface, then caused the large difference between radar-observed AH and its surface counterparts.
In addition, R(AH, ZDR) performed best of the six radar QPE estimators with respect to the ENM and ERMS scores shown in Table 1. Essentially, it is not straightforward to resolve the performance differences between R(KDP, ZDR) and R(AH, ZDR), since AH and KDP have similar characteristics. They are often related through AH = αKDP. Therefore, we aimed to decompose their mathematical formulas into two parts (see Figure 9). In particular, R(KDP, ZDR) consists of KDP- and ZDR-related components, whereas R(AH, ZDR) consists of AH- and ZDR-related components. Since the KDP- and AH-related calculations behave similarly (see Figure 9a,b), the ZDR-related components play a dominant role in the differences. We noticed that R(KDP, ZDR) is more associated with overestimation compared with R(AH, ZDR), and the ZDR-related calculation in R(AH, ZDR) decreases more quickly than that of R(KDP, ZDR) (see Figure 9c). All in all, the differences between R(KDP, ZDR) and R(AH, ZDR) are more related to the ZDR-related component. Besides, Figure 8f shows that many scatter dots were distributed below the diagonal line when gauge measurements were less than 10 mm, and these underestimates may partly compromise the overestimates when the 3-h gauge measurements exceeded 75 mm, which was an important reason for the superior scores of R(AH, ZDR).
The comparison between different radar QPE approaches showed that R(KDP) performs best of all the single-parameter radar QPE estimators in the range 0–75mm, and R(AH, ZDR) performs best with respect to ENM scores. However, this result cannot be declared just based on the statistical scores. Not all polarimetric radar QPE estimators, such as R(KDP, ZDR), can obtain superior statistical scores to R(ZH). Instead, the detailed scatter distributions in Figure 8c–f show that R(KDP), R(KDP, ZDR), R(AH), and R(AH, ZDR) were all overestimated when gauge measurements exceeded 50 mm. This indicates that manually alternating polarimetric radar variables cannot always obtain better performances. The rainfall center area is worthy of further investigation to reveal some negative factors, which seriously affect the practical performance of these polarimetric radar QPE algorithms.

3.4. Time Series Analysis

Gauge-measured, DSD-based, and radar-estimated hourly rainfall time series from ten meteorological stations, which are located within the rainfall center area shown in Figure 7, are shown in Figure 10. Although only CA and JD stations were used to observe the DSD dataset, the near agreement of DSD-based and gauge-measured hourly rainfall (bold black and green lines) shown in Figure 10a,b verifies the high quality of these gauge measurements; therefore, the gauge-measured rainfall time series of the other eight stations can also provide good surface reference rainfall for radar estimates too. Moreover, some typical error characteristics related to different radar rainfall patterns can be directly reflected through these temporal rainfall series.
Figure 10a shows a good positive example that nearly all radar-estimated rainfall series at CA station were in good accordance with the gauge-measured rainfall series with an exception of R(ZH), which was underestimated at 0200–0400 UTC. The time series at QDH at 0200–0500 UTC shown in Figure 10c and that at GX at 0300–0500 UTC shown in Figure 10d were very similar to those shown in Figure 10a. They can be assumed to have similar rainfall patterns. Although the optimum rainfall retrieval relationship is necessary for a good rainfall estimator, the small deviation between the radar-estimated rainfall series of R(AH), R(KDP), R(ZH, ZDR), R(AH, ZDR) and the gauge-measured rainfall series in Figure 10a can also be attributed to the consistency between the radar-observed series of ZH, ZDR, KDP, and AH and their T-matrix-derived counterparts in Figure 11a,c,e,g. Furthermore, most radar-observed and T-matrix-derived ρHV values exceed 0.99 in Figure 11i, which indicates that radar observed pure liquid hydrometeors up in the air are similar to those near the surface. Accordingly, the ellipses depicted in Figure 11c,d implies that the overestimated KDP and AH values observed by radar can account for their overestimated rainfall near 0200 UTC in Figure 10a too. On the contrary, the large deviation of R(ZH) from the gauge rainfall series can be attributed to the inadequate R(ZH) relationship, as described in Section 3.3.
The overestimation of the time series of R(AH), R(KDP), R(KDP, ZDR), R(AH, ZDR) at JD station at 0300–0400 UTC (Figure 10b), at ZY station at 0400–0500 UTC (Figure 10h), at GL station at 0300–0500 UTC (Figure 10i), and at JZL station at 0340–0440 UTC feature similar rainfall patterns. In contrast, the rainfall series estimated by R(ZH) and R(ZH, ZDR) agreed well with the gauge rainfall series in these time intervals. Some characteristics can be deduced from the data timeseries of JD station in Figure 12. The difference of ρHV depicted in Figure 12e indicates the hydrometeors in the radar beams and near the surface were microphysically different, namely, some solid hydrometeors may exist in the upper air, but only liquid hydrometeors fell on the surface. Thus, there existed an unobserved microphysical transition before the solid hydrometeors falling on the ground. The large ZDR values near the surface in Figure 12b corresponded to big raindrops at the start of the showers; however, radar-observed ZDR values were all less than 2 dB during this period, which indicates the diameter of the hydrometeors in the air were still smaller than 2 mm and the Mie scattering effects were not obvious in some radar volumes. Therefore, radar-observed KDP and AH in Figure 12c,d may be overestimated than expected if the contribution of the solid hydrometeors was not separated successfully from ΦDP. The reason for the small biases between radar-observed ZH and surface-T-matrix-derived ZH in Figure 12a can be ascribed to the fact that a large raindrop can account for a large number of little raindrops, namely, more large raindrops were observed near the surface than in the upper air, which had been verified by the large bias of ZDR. Consequently, radar-observed ZH and T-matrix-derived ZH might coincidently agree with each other and R(ZH) did not deviate far from the gauge-measured/DSD-based hourly rainfall series during this time period. Simultaneously, the ZDR-related calculations hardly reduced the overestimation caused by the AH-related or KDP-related calculations of R(AH, ZDR) and R(KDP, ZDR) during the same period. Instead, R(ZH, ZDR) outperformed the other five radar QPE estimators and its rainfall time series was most similar to the gauge-measured and DSD-based hourly rainfall series of JD station.
The time series of all radar estimates at SL and SC stations were all underestimated at 0200–0330, as shown in Figure 10e,f. The rainstorm system, which was featured abundant moisture (see Figure 5), moved along the northwest direction and successively affected SL, XH, and SC stations. These radar rainfall underestimations were caused by showers at the start of the major rainstorm. The detailed information of ZH, ZDR, and KDP, as well as the six-minute rainfall measurements at these three stations are all listed in Table 2, where the radar captured only one peak value each of ZH, ZDR, and KDP at SL and SC stations. However, the CPOL radar captured two peak values each of ZH, ZDR, and KDP at XH station. Through comparing the six-minute rainfall recordings from the gauges, SL, XH, and SC were found to have two peak values of ZH, ZDR, and KDP each. That is, the CPOL radar failed to detect the second peak values of ZH, ZDR, and KDP at SL and SC stations due to the rapid development and movement of the shower in front of the rainstorm. As a result, all radar estimates at SL and SC tended to underestimate the hourly rainfall accumulations, and this underestimation lasted for about one hour.
Figure 10h demonstrates another typical pattern where R(AH) and R(AH, ZDR) were both superior to R(KDP) and R(KDP, ZDR) and the latter two were both overestimated at 0230–0500 UTC. Since the optimal rainfall retrieval relationships were used, the performance difference was mainly attributed to the different characteristics of AH and KDP. AH is often estimated through AH = αKDP. In addition, the reconstructed ΦDP calculated through the fitting process (KDP fitting) or ZPHI processing (AH) should both be similar to the filtered ΦDP. Hence, it can be concluded that the major difference between AH and KDP is in the coefficient α, which is adjustable in [r0, rm]. Moreover, for the same ΔΦDP (r0, rm), it is well known that the difference in Z H M will not affect the AH because AH is also immune to attenuation, miscalibration, PBB, and wet radome issues. Based on Equation (1a), coefficient α must be different in the process in order to maintain such a statement. In the pure liquid rain scenario, both KDP and AH were expected to increase as the attenuation corrected ZH increased. For the mixed phase hydrometeors in the melting layer, both KDP and AH tended to be near-zero if ΔΦDP (r0, rm) could be constrained by a small value during the estimation process; otherwise, they might be overestimated if ΔΦDP (r0, rm) was large, which is similar to the pure rain scenario.
Furthermore, due to the changes in coefficient α, the consistency between AH and ZH is not as strong as that between KDP and ZH and/or ZDR (for details on the self-consistency of polarimetric radar measurements, see [39]). To further support such a conclusion, Figure 6 shows that the radar-observed KDP vs. ZH (Figure 6b) measurements are consistent with the T-matrix-derived scattergram of KDP vs. ZH. However, the radar-observed scattergram of AH vs. ZH (Figure 6c) is not as consistent. Instead, there is an obvious divergence when ZH exceeds 40 dBZ, which is more obvious than that of KDP vs. ZH in Figure 6b. Such divergence is further investigated using Figure 6c, which led to the separation of the radar-observed scattergram of AH vs. ZH into three categories:
(i) Radar-observed data overlap with the T-matrix-derived data: Radar-observed AH values within the range gates are nearly the same as T-matrix-derived AH. Using the optimal R(AH) relationships, unbiased R(AH) is expected compared with the R calculated directly from DSD and surface gauge rainfall measurements (see Figure 4e).
(ii) Radar-observed data above the T-matrix-derived data: These radar-observed AH values are potentially higher than the ideal observations near the surface, which is caused by the contamination of some small-sized melting hydrometeors with the diameter less than 2 mm. These radar-observed AH values may further cause the overestimation of R(AH) if radar-observed AH values are directly applied (Figure 4e). Due to the narrow range of AH, a little deviation may introduce a large difference in R(AH). As such, a correction procedure for AH may be required.
(iii) Radar-observed data below the T-matrix-derived data: This is dominated by the near-zero AH values, and their range gates are more associated with the melting mixed phase hydrometers. Although Z H M can be large in [r0, rm], ΔΦDP (r0, rm) may be small in Equation (1a) due to the non-negative constraint imposed on AH estimation, the coefficient α can adjust the non- Z H M part of Equation (1a), resulting in reconstructed ΦDP close to the filtered ΦDP.

3.5. Discussion

The statistical comparison in Section 3.3 actually gives an overall view of the error characteristics of these radar QPE estimators. More error information about each radar QPE estimator can be seen by comparing the time series of radar rainfall estimates with gauge rainfall measurements. This shows that the optimum rainfall rate relationships and the consistency between radar measurements and their surface counterparts are both indispensable, and the relative superiority of polarimetric radar QPE estimators is closely related to the specific rainfall patterns. The following should be noted:
(i) Regionally optimal rainfall estimation relationships are the basis for radar QPE. The C-band relations for R(ZH), R(AH), and R(KDP) provided in this paper are significantly different from those given in [23,40,41]. Similar comparable results may be not expected if the same equation parameters are directly implemented for severe rainfall events in this paper, because they may be representative of different localized precipitation characteristics, which intrinsically varies around the world. This is the reason why individual equations of R(ZH), R(AH), and R(KDP) are always necessary for different locations; (ii) R(ZH) is not always an optimal option for polarimetric radar. However, it was observed that R(ZH) is not always inferior to other rainfall estimators, and R(ZH) really performed best at 0100–0310 UTC (Figure 10b) and at 0100–0340 UTC (Figure 10h), where the time series of R(ZH) tended to overlap with the gauge time series in these specific temporal intervals. Besides, the overestimation effects caused by the melting layers on R(ZH) can be solved by some bright band identification procedure, and more adequate R(ZH) relationships suitable for severe rainfall scenario or self-adaptive R(ZH) relationships may further enhance the performance of R(ZH). Therefore, ZH is still useful for the range gates where KDP or AH is abnormally higher.
(iii) In this paper, R(ZH, ZDR) is a positive example of ZDR utilization and it performs better than R(ZH) in many of the time series depicted in Figure 10. Comparing the mathematical forms of R(ZH) and R(ZH, ZDR), the integration with ZDR really mitigates some underestimation of R(ZH). In contrast, R(KDP, ZDR) presented more overestimates than R(KDP), which implies that integrating ZDR with KDP through current mathematical form may not be effective. In addition, although R(AH, ZDR) obtained the best ENM scores, it underestimated in light rainfall scenarios more seriously than R(AH). Some regional correction upon the rainfall field derived from R(KDP, ZDR) and R(AH, ZDR) may be necessary to improve their performance.
(iv) The melting layer not only causes the overestimation of R(ZH) but can also introduce overestimation to R(AH) and R(KDP). If radar-observed KDP or AH were contaminated by the melting layer but the hydrometeors near the surface were not, R(KDP) and R(AH) might be overestimated. Although the α coefficient can adjust to mitigate some bias of R(AH), which helps it to outperform R(KDP), the overestimation related to R(AH) remains serious. Some correction procedures aiming to make radar-observed AH or KDP more approximate to the counterparts of surface hydrometers have shown promise for future use; however, some statistical prior knowledge on the regional rainfall characteristics may be necessary during this process.
(v) The convective rainstorms with a quick moving speed may cause all radar QPE estimators to be underestimated if the radar failed to capture the full view of the rainstorm. Such rainfall patterns correspond to the initial developing phase of the rainstorms. The low-cost gap-filling X-band radar network may help to instantly observe such rainstorms in their initial developing phase. The phased array radar supporting quick VCP scanning strategy also helps to provide high temporal resolution dataset for such rainstorms. Both are promising to make the monitoring of rainstorms more spatiotemporally seamless for radar QPE retrievals.
Dynamic composition of the different radar QPE estimators is a promising trend, and all of the different radar rainfall estimators can be comprehensively utilized in this way. However, the optimal and representative relationships incorporating a variety of rainfall characteristics over a target area, the high-quality radar measurements similar to the counterparts of surface hydrometeors, and the detailed composition forms of these radar QPE estimators are all important factors that make the ultimate rainfall estimation results efficient in practical operations. None of the abovementioned issues can be neglected during this process and they are worthy of further investigation in the future.

4. Summary

Efficient utilization of the polarimetric radar variables to estimate rainfall is critical for timely severe rainfall warnings and subsequent hydrometeorological applications. Polarimetric radar has provided many possible combinations of different QPE estimators. This paper evaluated the performance of three single-parameter and three double-parameter-based radar QPE relations using CPOL radar measurements during a severe waterlogging event in eastern China. The evaluation scores, scattergrams and the rainfall time series within the rainfall field center were compared in details. The main findings are summarized as follows:
(i) R(AH, ZDR) performed the best among the six QPE estimators in this waterlogging event according to the ENM score, although it introduced underestimation in light rain areas. The incorporation of ZDR improved the performance of both R(ZH, ZDR) and R(AH, ZDR) over their single- parameter counterparts, but the improvement was negligible in R(KDP, ZDR) during this particular event. The basic calculation form of the ZDR-related component in R(KDP, ZDR) may be responsible for this phenomenon.
(ii) In addition to the optimal rainfall relationship, the consistency between radar measurements aloft and their surface counterparts was also necessary for accurate rainfall estimation near ground level. The contamination of melting solid hydrometeors on AH and KDP can make R(AH), R(AH, ZDR), R(KDP), and R(KDP, ZDR) less effective than R(ZH) and R(ZH,ZDR). In addition, the adjustment of the α coefficient for estimating AH can partly reduce some of the impact of melting hydrometeors and thus improve the performance of the AH–based rainfall estimator.
(iii) The practical performance and relative advantages of different radar QPE estimators are seriously affected by different rainfall patterns. On the one hand, all radar QPE estimators tend to underestimate rainfall if the radar failed to capture the rapid evolvement of the rainstorms. On the other hand, each radar QPE estimator can outperform others during some time intervals with particular rainfall characteristics.
In summary, utilizing polarimetric techniques to improve radar QPE is not as simple as just replacing radar variables in the radar rainfall relations. Instead, the identification of different rainfall characteristics and the implementation of optimal or adaptive rainfall algorithms are critical for obtaining accurate QPE data. In addition, the use of high-resolution gap-filling X-band radar networks (e.g., [42]) or phased array radars is a promising way to further enhance the radar-derived rainfall product.

Author Contributions

Y.G. carried out the data collection and detailed analysis. Y.G. was also involved in the development of the polarimetric radar data processing and product generation systems. H.C. and J.Z. supervised the work and provided critical comments. J.Z. conducted the detailed literature review. Y.G. and H.C. prepared the first draft of this manuscript. J.Z. reviewed and edited the manuscript.

Funding

This research was primarily supported by the National Natural Science Foundation of China (NSFC) under grant 41705018 and the Zhejiang Provincial Natural Science Fund through award LY17D050001.

Acknowledgments

The C-band polarimetric radar and gauge data were provided by the Hangzhou Meteorological Bureau (HMB). The authors would like to thank the forecasters at HMB for the discussion of this severe weather event. Thanks to the anonymous reviewers for their great comments that helped us improve this manuscript.

Conflicts of Interest

The authors declare no conflicts of interest.

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Figure 1. (a) Topography around the C-band polarimetric (CPOL) radar (red “+”); (b) gauge network (black “+”) within 100 km of the CPOL radar; the Parsivel2 disdrometers deployed at CA and JD are marked with red dots on (a) and (b); (c) the severe rainfall domain (i.e., the rectangle in (a)) around the TIL area and sample photos taken during the 1 June 2016 event. Eight stations with the largest 3-h rainfall quantities and two disdrometer stations are marked with a red “+” in (c).
Figure 1. (a) Topography around the C-band polarimetric (CPOL) radar (red “+”); (b) gauge network (black “+”) within 100 km of the CPOL radar; the Parsivel2 disdrometers deployed at CA and JD are marked with red dots on (a) and (b); (c) the severe rainfall domain (i.e., the rectangle in (a)) around the TIL area and sample photos taken during the 1 June 2016 event. Eight stations with the largest 3-h rainfall quantities and two disdrometer stations are marked with a red “+” in (c).
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Figure 2. The relative frequency (Freq.%) of pixels with ZH > 20 dBZ within range of 180 km from the CPOL radar: (a) Before GC mitigation; (b) After GC mitigation.
Figure 2. The relative frequency (Freq.%) of pixels with ZH > 20 dBZ within range of 180 km from the CPOL radar: (a) Before GC mitigation; (b) After GC mitigation.
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Figure 3. Scattergram of radar variables simulated using the DSD dataset collected on 0000–2359 UTC on 01 June 2016: (a) ZDR vs. ZH; (b) KDP vs. ZH, (c) AH vs. ZH, and (d) AH vs. KDP. The black curve in (a) represents the ZDRZH relationship in Equation (2a).
Figure 3. Scattergram of radar variables simulated using the DSD dataset collected on 0000–2359 UTC on 01 June 2016: (a) ZDR vs. ZH; (b) KDP vs. ZH, (c) AH vs. ZH, and (d) AH vs. KDP. The black curve in (a) represents the ZDRZH relationship in Equation (2a).
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Figure 4. Scattergram between T-matrix-derived polarimetric radar variables, as well as estimated/ regressed R based on the simulated radar variables using the raindrop size distribution (DSD) data collected on 01 June 2016: (a) R(ZH); (b) R(ZH, ZDR); (c) R(KDP); (d) R(KDP, ZDR); (e) R(AH); (f) R(AH, ZDR). The black lines in (a–c) represent Equations (3a), (3c), and (3e), respectively. T-matrix-derived R stands for R calculated directly from the DSD data.
Figure 4. Scattergram between T-matrix-derived polarimetric radar variables, as well as estimated/ regressed R based on the simulated radar variables using the raindrop size distribution (DSD) data collected on 01 June 2016: (a) R(ZH); (b) R(ZH, ZDR); (c) R(KDP); (d) R(KDP, ZDR); (e) R(AH); (f) R(AH, ZDR). The black lines in (a–c) represent Equations (3a), (3c), and (3e), respectively. T-matrix-derived R stands for R calculated directly from the DSD data.
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Figure 5. Radar plan position indicator (PPI) scan at an elevation angle of 0° at 0330 UTC on 1 June 2016: (a) Vr; (b) ΦDP; (c) ZH; (d) ZDR; (e) KDP and (f) AH. The relative positions of CA and JD are marked with “+”. The bold arrows in (a) describe the northwestern and the southwestern winds.
Figure 5. Radar plan position indicator (PPI) scan at an elevation angle of 0° at 0330 UTC on 1 June 2016: (a) Vr; (b) ΦDP; (c) ZH; (d) ZDR; (e) KDP and (f) AH. The relative positions of CA and JD are marked with “+”. The bold arrows in (a) describe the northwestern and the southwestern winds.
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Figure 6. The scattergrams between different radar variables at a scan elevation angle of 0° at 0330 UTC on 1 June 2016: (a) ZDR vs. ZH (b) KDP vs. ZH; (c) AH vs. ZH, (d) AH vs. KDP. The black dots stand for the simulated radar variables based on the drop size distribution measurements.
Figure 6. The scattergrams between different radar variables at a scan elevation angle of 0° at 0330 UTC on 1 June 2016: (a) ZDR vs. ZH (b) KDP vs. ZH; (c) AH vs. ZH, (d) AH vs. KDP. The black dots stand for the simulated radar variables based on the drop size distribution measurements.
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Figure 7. Three hour rainfall accumulation based on six different radar rainfall estimators at 0500 UTC on 1 June 2016: (a) R(ZH); (b) R(ZH, ZDR); (c) R(KDP); (d) R(KDP,ZDR). (e) R(AH); (f) R(AH, ZDR). Ten meteorological stations are marked with “+”.
Figure 7. Three hour rainfall accumulation based on six different radar rainfall estimators at 0500 UTC on 1 June 2016: (a) R(ZH); (b) R(ZH, ZDR); (c) R(KDP); (d) R(KDP,ZDR). (e) R(AH); (f) R(AH, ZDR). Ten meteorological stations are marked with “+”.
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Figure 8. Scattergram of 3-h rainfall estimates from the gauge versus radar using six different radar rainfall estimators at 0500 UTC on 1 June 2016: (a) R(ZH); (b) R(ZH, ZDR); (c) R(KDP); (d) R(KDP,ZDR); (e) R(AH); (f) R(AH, ZDR).
Figure 8. Scattergram of 3-h rainfall estimates from the gauge versus radar using six different radar rainfall estimators at 0500 UTC on 1 June 2016: (a) R(ZH); (b) R(ZH, ZDR); (c) R(KDP); (d) R(KDP,ZDR); (e) R(AH); (f) R(AH, ZDR).
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Figure 9. Different radar variable related components: (a) KDP-related component; (b)AH-related component; (c)ZDR-related component.
Figure 9. Different radar variable related components: (a) KDP-related component; (b)AH-related component; (c)ZDR-related component.
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Figure 10. Time series of hourly rainfall estimates for 60 minute moving windows from the 10 gauges, disdrometer and radar between 0100–0700 UTC on 1 June 2016: (a) CA, (b) JD, (c) QDH, (d) GX, (e) SL, (f) SC, (g) XH, (h) ZY, (e) GL and (j) JZL.
Figure 10. Time series of hourly rainfall estimates for 60 minute moving windows from the 10 gauges, disdrometer and radar between 0100–0700 UTC on 1 June 2016: (a) CA, (b) JD, (c) QDH, (d) GX, (e) SL, (f) SC, (g) XH, (h) ZY, (e) GL and (j) JZL.
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Figure 11. T-matrix-derived radar variables and CPOL radar measurements at CA station at 0100–0700 UTC on 1 June 2016: (a) ZH, (b) ZDR, (c) KDP, (d) AH, and (e) ρHV. The ellipses on (c) and (d) indicate that the radar-observed KDP and AH values are larger than the T-matrix-simulated ones.
Figure 11. T-matrix-derived radar variables and CPOL radar measurements at CA station at 0100–0700 UTC on 1 June 2016: (a) ZH, (b) ZDR, (c) KDP, (d) AH, and (e) ρHV. The ellipses on (c) and (d) indicate that the radar-observed KDP and AH values are larger than the T-matrix-simulated ones.
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Figure 12. T-matrix-derived radar variables and CPOL radar measurements at JD station at 0100–0700 UTC on 1 June 2016: (a) ZH, (b) ZDR, (c) KDP, (d) AH, and (e) ρHV. The ellipses on (b–e) indicate larger radar-observed KDP and AH values but smaller ZDR and ρHV values than T-matrix-derived ones.
Figure 12. T-matrix-derived radar variables and CPOL radar measurements at JD station at 0100–0700 UTC on 1 June 2016: (a) ZH, (b) ZDR, (c) KDP, (d) AH, and (e) ρHV. The ellipses on (b–e) indicate larger radar-observed KDP and AH values but smaller ZDR and ρHV values than T-matrix-derived ones.
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Table 1. Evaluation scores of the 3-h rainfall estimates from the CPOL radar.
Table 1. Evaluation scores of the 3-h rainfall estimates from the CPOL radar.
ScoresRadar QPE Estimators
R(ZH)R(ZH, ZDR)R(KDP)R(KDP, ZDR)R(AH)R(AH, ZDR)
ERMS (mm)5.6404.0675.778.3966.0045.197
ENM–11.974–8.57712.4521.5816.088–4.398
ECC0.9790.9830.9810.9760.9780.976
Table 2. Radar measurements and six-minute gauge rainfall measurements of the three stations during 0212–0330 UTC on 1 June 2016. The bold font marks first two timeframes of the shower at each station.
Table 2. Radar measurements and six-minute gauge rainfall measurements of the three stations during 0212–0330 UTC on 1 June 2016. The bold font marks first two timeframes of the shower at each station.
Time (UTC)ZH (dBZ)ZDR (dB)KDP (deg·km-1)Gauge Rainfall (mm)
SLXHSCSLXHSCSLXHSCSLXHSC
021253.6--2.06--4.50--13.70.00.0
021816.551.8-0.12.05-0.06.89-11.912.70.0
022440.950.8-1.192.90-1.193.24-1.78.20.1
023011.335.254.40.60.871.850.200.415.883.22.914.3
023622.916.715.90.020.031.780.04-0.7333.93.912.7
024227.322.120.10.460.070.210.000.060.011.10.67.5
024828.536.539.10.250.731.430.030.020.751.70.11.1
025449.943.829.41.971.390.332.950.460.343.20.20.1
030040.544.744.70.851.231.210.350.731.234.61.90.9
030633.545.431.70.491.070.530.261.700.093.86.32.7
031247.443.746.81.391.051.442.960.721.904.41.83.6
031844.940.648.50.690.941.071.260.893.546.62.34.1
032447.939.847.71.260.721.152.270.470.887.16.44.6
033049.245.733.81.030.960.372.511.320.367.03.63.0

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Gou, Y.; Chen, H.; Zheng, J. Polarimetric Radar Signatures and Performance of Various Radar Rainfall Estimators during an Extreme Precipitation Event over the Thousand-Island Lake Area in Eastern China. Remote Sens. 2019, 11, 2335. https://doi.org/10.3390/rs11202335

AMA Style

Gou Y, Chen H, Zheng J. Polarimetric Radar Signatures and Performance of Various Radar Rainfall Estimators during an Extreme Precipitation Event over the Thousand-Island Lake Area in Eastern China. Remote Sensing. 2019; 11(20):2335. https://doi.org/10.3390/rs11202335

Chicago/Turabian Style

Gou, Yabin, Haonan Chen, and Jiafeng Zheng. 2019. "Polarimetric Radar Signatures and Performance of Various Radar Rainfall Estimators during an Extreme Precipitation Event over the Thousand-Island Lake Area in Eastern China" Remote Sensing 11, no. 20: 2335. https://doi.org/10.3390/rs11202335

APA Style

Gou, Y., Chen, H., & Zheng, J. (2019). Polarimetric Radar Signatures and Performance of Various Radar Rainfall Estimators during an Extreme Precipitation Event over the Thousand-Island Lake Area in Eastern China. Remote Sensing, 11(20), 2335. https://doi.org/10.3390/rs11202335

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