Rain Attenuation Correction of Reflectivity for X-Band Dual-Polarization Radar

The values of ratio a of the linear relationship between specific attenuation and specific differential phase vary significantly in convective storms as a result of resonance scattering. The best-linear-fit ratio a at X band is determined using the modified attenuation correction algorithm based on differential phase and attenuation, as well as the premise that reflectivity is unattenuated in S band radar detection. Meanwhile, the systemic reflectivity bias between the X band radar and S band radar and water layer attenuation (ZW) on the wet antenna cover of the X band radar are also considered. The good performance of the modified correction algorithm is demonstrated in a moderate rainfall event. The data were collected by four X band dual-polarization (X-POL) radar sites, namely, BJXCP, BJXFS, BJXSY, and BJXTZ, and a China’s New Generation Weather Radar (CINRAD/SA radar) site, BJSDX, in Beijing on 20 July 2016. Ratio a is calculated for each volume scan of the X band radar, with a mean value of 0.26 dB deg−1 varying from 0.20 to 0.31 dB deg−1. The average values of systemic reflectivity bias between the X band radar (at BJXCP, BJXFS, BJXSY, and BJXTZ) and S band radar (at BJSDX) are 0, −3, 2, and 0 dB, respectively. The experimentally determined ZW is in substantial agreement with the theoretically calculated ones, and their values are an order of magnitude smaller than rain attenuation. The comparison of the modified attenuation correction algorithm and the empirical-fixed-ratio correction algorithm is further evaluated at the X-POL radar. It is shown that the modified attenuation correction algorithm in the present paper provides higher correction accuracy for rain attenuation than the empirical-fixed-ratio correction algorithm.

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Correction of X-Band Radar Observation for Propagation Effects Based on the Self-Consistency Principle

Journal of Atmospheric and Oceanic Technology ◽

10.1175/jtech1950.1 ◽

2006 ◽

Vol 23 (12) ◽

pp. 1668-1681 ◽

Cited By ~ 45

Author(s):

Eugenio Gorgucci ◽

V. Chandrasekar ◽

Luca Baldini

Keyword(s):

Attenuation Correction ◽

Rain Attenuation ◽

The Self ◽

Dual Polarization ◽

Adaptive Sensing ◽

Rain Medium ◽

X Band ◽

Differential Reflectivity ◽

Self Consistency ◽

New Algorithms

Abstract New algorithms for rain attenuation correction of reflectivity factor and differential reflectivity are presented. Following the methodology suggested for the first time by Gorgucci et al., the new algorithms are developed based on the self-consistency principle, describing the interrelation between polarimetric measurements along the rain medium. There is an increasing interest in X-band radar systems, owing to the early success of the attenuation-correction procedures as well as the initiative of the Center for Collaborative Adaptive Sensing of the Atmosphere to deploy X-band radars in a networked fashion. In this paper, self-consistent algorithms for correcting attenuation and differential attenuation are developed. The performance of the algorithms for application to X-band dual-polarization radars is evaluated extensively. The evaluation is conducted based on X-band dual-polarization observations generated from S-band radar measurements. Evaluation of the new self-consistency algorithms shows significant improvement in performance compared to the current class of algorithms. In the case that reflectivity and differential reflectivity are calibrated between ±1 and ±0.2 dB, respectively, the new algorithms can estimate both attenuation and differential attenuation with less than 10% bias and 15% random error. In addition, the attenuation-corrected reflectivity and differential reflectivity are within 1–0.2 dB 96% and 99% of the time, respectively, demonstrating the good performance.

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X-band Polarimetric Radar Rainfall Measurements in Keys Area Microphysics Project

Journal of the Atmospheric Sciences ◽

10.1175/jas3592.1 ◽

2006 ◽

Vol 63 (1) ◽

pp. 187-203 ◽

Cited By ~ 25

Author(s):

Emmanouil N. Anagnostou ◽

Mircea Grecu ◽

Marios N. Anagnostou

Keyword(s):

Phase Shift ◽

Attenuation Correction ◽

Doppler Radar ◽

Model Parameters ◽

Dual Polarization ◽

Radar Rainfall ◽

Differential Phase Shift ◽

Differential Phase ◽

X Band ◽

Filter Noise

Abstract The Keys Area Microphysics Project (KAMP), conducted as part of NASA’s Fourth Convective and Moisture Experiment (CAMEX-4) in the lower Keys area, deployed a number of ground radars and four arrays of rain gauge and disdrometer clusters. Among the various instruments is an X-band dual-polarization Doppler radar on wheels (XPOL), contributed by the University of Connecticut. XPOL was used to retrieve rainfall rate and raindrop size distribution (DSD) parameters to be used in support of KAMP science objectives. This paper presents the XPOL measurements in KAMP and the algorithm developed for attenuation correction and estimation of DSD model parameters. XPOL observations include the horizontal polarization reflectivity ZH, differential reflectivity ZDR, and differential phase shift ΦDP. Here, ZH and ZDR were determined to be positively biased by 3 and 0.3 dB, respectively. A technique was also applied to filter noise and correct for potential phase folding in ΦDP profiles. The XPOL attenuation correction uses parameterizations that relate the path-integrated specific (differential) attenuation along a radar ray to the filtered-ΦDP (specific attenuation) profile. Attenuation-corrected ZH and specific differential phase shift (derived from filtered ΦDP profiles) data are then used to derive two parameters of the normalized gamma DSD model, that is, intercept (Nw) and mean drop diameter (D0). The third parameter (shape parameter μ) is calculated using a constrained μ–Λ relationship derived from the measured raindrop spectra. The XPOL attenuation correction is evaluated using coincidental nonattenuated reflectivity fields from the Key West Weather Surveillance Radar-1988 Doppler (WSR-88D), while the DSD parameter retrievals are statistically assessed using DSD parameters calculated from the measured raindrop spectra. Statistics show that XPOL DSD parameter estimation is consistent with independent observations. XPOL estimates of water content and Nw are also shown to be consistent with corresponding retrievals from matched ER-2 Doppler radar (EDOP) profiling observations from the 19 September airborne campaign. Results shown in this paper strengthen the applicability of X-band dual-polarization high resolution observations in cloud modeling and precipitation remote sensing studies.

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Evaluation of Attenuation Correction Methodology for Dual-Polarization Radars: Application to X-Band Systems

Journal of Atmospheric and Oceanic Technology ◽

10.1175/jtech1763.1 ◽

2005 ◽

Vol 22 (8) ◽

pp. 1195-1206 ◽

Cited By ~ 40

Author(s):

Eugenio Gorgucci ◽

V. Chandrasekar

Keyword(s):

Attenuation Correction ◽

High Frequency ◽

Lower Cost ◽

Dual Polarization ◽

Phase Measurements ◽

Differential Phase ◽

High Frequency Radar ◽

Radar Systems ◽

X Band ◽

The Impact

Abstract Monitoring of precipitation using high-frequency radar systems, such as the X band, is becoming increasingly popular because of their lower cost compared to their S-band counterpart. However, at higher frequencies, such as the X band, the precipitation-induced attenuation is significant, and introduces ambiguities in the interpretation of the radar observations. Differential phase measurements have been shown to be very useful for correcting the measured reflectivity for precipitation-induced attenuation. This paper presents a quantitative evaluation of two attenuation correction methodologies with specific emphasis on the X band. A simple differential phase–based algorithm as well as the range-profiling algorithm are studied. The impact of backscatter differential phase on the performance of attenuation correction is evaluated. It is shown that both of the algorithms for attenuation correction work fairly well, yielding attenuation-accurate corrected reflectivities with a negligible bias.

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Attenuation Correction of X-Band Radar Reflectivity Using Adjacent Multiple Microwave Links

Remote Sensing ◽

10.3390/rs12132133 ◽

2020 ◽

Vol 12 (13) ◽

pp. 2133

Author(s):

Min-Seong Kim ◽

Byung Hyuk Kwon

Keyword(s):

Attenuation Correction ◽

Rain Attenuation ◽

Physical Structure ◽

Radar Reflectivity ◽

Correction Coefficient ◽

Polarimetric Radar ◽

Weather Radars ◽

X Band ◽

Rainfall Type ◽

Microwave Link

Rain attenuation can hinder the implementation of quantitative precipitation estimations using X-band weather radar. Numerous studies have been conducted on correcting the attenuation of radar reflectivity by utilizing a dual-polarimetric radar and an arbitrary-oriented microwave link; however, there is a need to optimize the required number of microwave links and their locations. In this study, we tested four attenuation correction methods and proposed a novel algorithm based on the sole use of adjacent multiple microwave links. The attenuation of the X-band radar reflectivity was corrected by performing forward iterations at each link, and the correction coefficients were statistically analyzed to reduce the instability problem. The algorithms of each method were evaluated by studying the cases of convective and stratiform rainfall, and then validated by comparing the corrected reflectivity of the X-band radar with the qualitatively controlled reflectivity of the S-band radar. The new method was as efficient as the conventional method based on the specific differential phase of dual-polarimetric radar. Furthermore, the correction coefficient was more effectively optimized and stabilized using seven microwave links rather than a single link, and no further independent reference data were required. In addition, the attenuation correction also accounted for spatiotemporal differentiation depending on the rainfall type, and could recover the physical structure of the rainfall. The method developed herein can facilitate estimations of quantitative rainfall in developing countries where dual-polarization weather radars are not common. The exploitation of microwave link data is a promising method for rainfall remote sensing.

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Attenuation Correction Effects in Rainfall Estimation at X-Band Dual-Polarization Radar: Evaluation with a Dense Rain Gauge Network

Advances in Meteorology ◽

10.1155/2016/9716535 ◽

2016 ◽

Vol 2016 ◽

pp. 1-20 ◽

Cited By ~ 2

Author(s):

Young-A Oh ◽

DaeHyung Lee ◽

Sung-Hwa Jung ◽

Kyung-Yeub Nam ◽

GyuWon Lee

Keyword(s):

Attenuation Correction ◽

Random Error ◽

Estimation Method ◽

Rain Gauge ◽

Spatial Average ◽

Dual Polarization ◽

Rainfall Estimation ◽

Radar Rainfall ◽

X Band ◽

Rain Gauge Network

The effects of attenuation correction in rainfall estimation with X-band dual-polarization radar were investigated with a dense rain gauge network. The calibration bias in reflectivity (ZH) was corrected using a self-consistency principle. The attenuation correction ofZHand the differential reflectivity (ZDR) were performed by a path integration method. After attenuation correction,ZHandZDRwere significantly improved, and their scatter plots matched well with the theoretical relationship betweenZHandZDR. The comparisons between the radar rainfall estimation and the rain gauge rainfall were investigated using the bulk statistics with different temporal accumulations and spatial averages. The bias significantly improves from 70% to 0% withR(ZH). However, the improvement withR(ZH,ZDR)was relatively small, from 3% to 1%. This indicated that rainfall estimation using a polarimetric variable was more robust at attenuation than was a single polarimetric variable method. The bias did not show improvement in comparisons between the temporal accumulations or the spatial averages in either rainfall estimation method. However, the random error improved from 68% to 25% with different temporal accumulations or spatial averages. This result indicates that temporal accumulation or spatial average (aggregation) is important to reduce random error.

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

Journal of Atmospheric and Oceanic Technology ◽

10.1175/2010jtecha1407.1 ◽

2010 ◽

Vol 27 (8) ◽

pp. 1265-1285 ◽

Cited By ~ 29

Author(s):

D-S. Kim ◽

M. Maki ◽

D-I. Lee

Keyword(s):

Size Distribution ◽

Attenuation Correction ◽

Earth Science ◽

Three Dimensional ◽

Radar Data ◽

Rain Attenuation ◽

Polarimetric Radar ◽

Horizontal Polarization ◽

Differential Phase ◽

X Band

Abstract An improved algorithm based on the self-consistent principle for rain attenuation correction of reflectivity ZH and differential reflectivity ZDR are presented for X-band radar. The proposed algorithm calculates the optimum coefficients for the relation between the specific attenuation coefficient and the specific differential phase, every 1 km along a slant range. The attenuation-corrected ZDR is calculated from reflectivity at horizontal polarization and from reflectivity at vertical polarization after attenuation correction. The improved rain attenuation correction algorithm is applied to the range–height indicator (RHI) scans as well as the plan position indicator (PPI) volume scan data observed by X-band wavelength (MP-X) radar, as operated by the National Research Institute for Earth Science and Disaster Prevention (NIED) in Japan. The corrected ZH and ZDR values are in good agreement with those calculated from the drop size distribution (DSD) measured by disdrometers. The two governing parameters of a normalized gamma DSD, normalized number concentration NW, and drop median diameter D0 are estimated from the corrected ZH and ZDR, and specific differential phase KDP values based on the “constrained-gamma” method. The method is applied to PPI and RHI data of a typhoon rainband to retrieve the three-dimensional distribution of DSD. The retrieved DSD parameters show reasonable agreement with disdrometer data. The present results demonstrate that high-quality correction and retrieval DSDs can be derived from X-band polarimetric radar data.

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Attenuation Correction and Hydrometeor Classification of High-Resolution, X-band, Dual-Polarized Mobile Radar Measurements in Severe Convective Storms

Journal of Atmospheric and Oceanic Technology ◽

10.1175/2010jtecha1356.1 ◽

2010 ◽

Vol 27 (12) ◽

pp. 1979-2001 ◽

Cited By ~ 82

Author(s):

Jeffrey C. Snyder ◽

Howard B. Bluestein ◽

Guifu Zhang ◽

Stephen J. Frasier

Keyword(s):

High Resolution ◽

Attenuation Correction ◽

Dual Frequency ◽

Dual Polarization ◽

Frequency Method ◽

High Resolution Data ◽

Convective Storms ◽

Radar Systems ◽

X Band ◽

Dual Polarized

Abstract X-band and shorter radar wavelengths are preferable for mobile radar systems because a narrow beam can be realized with a moderately sized antenna. However, attenuation by precipitation becomes progressively more severe with decreasing radar wavelength. As a result, X band has become a popular choice for meteorological radar systems that balances these two considerations. Dual-polarization provides several methods by which this attenuation (and differential attenuation) can be detected and corrected, mitigating one of the primary disadvantages of X-band radars. The dynamics of severe convective storms depend, to some extent, on the distribution and type of hydrometeors within the storm. To estimate the three-dimensional distribution of hydrometeors using X-band radar data, it is necessary to correct for attenuation before applying commonly used hydrometeor classification algorithms. Since 2002, a mobile dual-polarized Doppler weather radar designed at the University of Massachusetts, Amherst has been used to collect high-resolution data in severe convective storms in the plains. This study tests several attenuation correction procedures using dual-polarization measurements, along with a dual-frequency method using S-band Weather Surveillance Radar-1988 Doppler (WSR-88D) and KOUN data. After correcting for attenuation and differential attenuation, a fuzzy logic hydrometeor classification algorithm, modified for X band with KOUN data as a reference, is used to attempt a retrieval of hydrometeor types in observed severe convective storms.

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A STUDY ON THE EFFECTS OF RAIN ATTENUATION FOR AN X-BAND SATELLITE SYSTEM OVER MALAYSIA

Progress In Electromagnetics Research B ◽

10.2528/pierb12083108 ◽

2012 ◽

Vol 45 ◽

pp. 37-56 ◽

Cited By ~ 2

Author(s):

Thiagarajah Siva Priya ◽

Thinagaran Nizanthi

Keyword(s):

Satellite System ◽

Rain Attenuation ◽

X Band

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Precipitation Classification and Quantification Using X-Band Dual-Polarization Weather Radar: Application in the Hydrometeorology Testbed

Journal of Atmospheric and Oceanic Technology ◽

10.1175/jtech-d-12-00123.1 ◽

2013 ◽

Vol 30 (9) ◽

pp. 2108-2120 ◽

Cited By ~ 26

Author(s):

S. Lim ◽

R. Cifelli ◽

V. Chandrasekar ◽

S. Y. Matrosov

Keyword(s):

Quality Control ◽

Phase Retrieval ◽

Estimation Method ◽

Rain Gauge ◽

Dual Polarization ◽

Rainfall Estimation ◽

Differential Phase ◽

Melting Region ◽

X Band ◽

Fuzzy Logic Technique

Abstract This paper presents new methods for rainfall estimation from X-band dual-polarization radar observations along with advanced techniques for quality control, hydrometeor classification, and estimation of specific differential phase. Data collected from the Hydrometeorology Testbed (HMT) in orographic terrain of California are used to demonstrate the methodology. The quality control and hydrometeor classification are specifically developed for X-band applications, which use a “fuzzy logic” technique constructed from the magnitude of the copolar correlation coefficient and the texture of differential propagation phase. In addition, an improved specific differential phase retrieval and rainfall estimation method are also applied. The specific differential phase estimation is done for both the melting region and rain region, where it uses a conventional filtering method for the melting region and a self-consistency-based method that distributes the total differential phase consistent with the reflectivity factor for the rain region. Based on the specific differential phase, rainfall estimations were computed using data obtained from the NOAA polarimetric X-band radar for hydrometeorology (HYDROX) and evaluated using HMT rain gauge observations. The results show that the methodology works well at capturing the high-frequency rainfall variations for the events analyzed herein and can be useful for mountainous terrain applications.

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