Improved Rain Attenuation Correction Algorithms for Radar Reflectivity and Differential Reflectivity with Adaptation to Drop Shape Model Variation

Abstract In this two-part paper, a correction for rain attenuation of radar reflectivity (ZH) and differential reflectivity (ZDR) at the X-band wavelength is presented. The correction algorithm that is used is based on the self-consistent method with constraints proposed by Bringi et al., which was originally developed and evaluated for C-band polarimetric radar data. The self-consistent method is modified for the X-band frequency and is applied to radar measurements made with the multiparameter radar at the X-band wavelength (MP-X) operated by the National Research Institute for Earth Science and Disaster Prevention (NIED) in Japan. In this paper, characteristic properties of relations among polarimetric variables, such as AH–KDP, ADP–AH, AH–ZH, and ZDR–ZH, that are required in the correction methodology are presented for the frequency of the MP-X radar (9.375 GHz), based on scattering simulations using drop spectra measured by disdrometers at the surface. The scattering simulations were performed under conditions of three different temperatures and three different relations for drop shapes, in order to consider variability of polarimetric variables for these conditions. For the X-band wavelength, the AH–KDP and ADP–AH relations can be assumed to be nearly linear. The coefficient α of the AH–KDP relation varies over a wide range from 0.139 to 0.335 dB (°)−1 with a mean value of 0.254 dB (°)−1. The coefficient γ of the ADP–AH relation varies from 0.114 to 0.174, with a mean value of 0.139. The exponent b of the AH–ZH relation does not depend on drop shapes and is almost constant for a given temperature (about 0.78 at the temperature of 15°C). The ZDR–ZH relation depends primarily on drop shape, and does not vary with temperature.

Download Full-text

Correcting C-band radar reflectivity and differential reflectivity data for rain attenuation: a self-consistent method with constraints

IEEE Transactions on Geoscience and Remote Sensing ◽

10.1109/36.951081 ◽

2001 ◽

Vol 39 (9) ◽

pp. 1906-1915 ◽

Cited By ~ 153

Author(s):

V.N. Bringi ◽

T.D. Keenan ◽

V. Chandrasekar

Keyword(s):

Rain Attenuation ◽

Radar Reflectivity ◽

Self Consistent ◽

Consistent Method ◽

Reflectivity Data ◽

Differential Reflectivity

Download Full-text

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.

Download Full-text

Comparison of Disdrometer and X-Band Mobile Radar Observations in Convective Precipitation

Monthly Weather Review ◽

10.1175/mwr-d-14-00039.1 ◽

2014 ◽

Vol 142 (7) ◽

pp. 2414-2435 ◽

Cited By ~ 11

Author(s):

Evan A. Kalina ◽

Katja Friedrich ◽

Scott M. Ellis ◽

Donald W. Burgess

Keyword(s):

Attenuation Correction ◽

Numerical Models ◽

Radar Data ◽

Convective Precipitation ◽

Radar Signal ◽

Squall Line ◽

Drop Shape ◽

X Band ◽

Signal Quality Index ◽

Differential Reflectivity

Abstract Microphysical data from thunderstorms are sparse, yet they are essential to validate microphysical schemes in numerical models. Mobile, dual-polarization, X-band radars are capable of providing a wealth of data that include radar reflectivity, drop shape, and hydrometeor type. However, X-band radars suffer from beam attenuation in heavy rainfall and hail, which can be partially corrected with attenuation correction schemes. In this research, the authors compare surface disdrometer observations to results from a differential phase-based attenuation correction scheme. This scheme is applied to data recorded by the National Oceanic and Atmospheric Administration (NOAA) X-band dual-polarized (NOXP) mobile radar, which was deployed during the second Verification of the Origins of Rotation in Tornadoes Experiment (VORTEX2). Results are presented from five supercell thunderstorms and one squall line (183 min of data). The median disagreement (radar–disdrometer) in attenuation-corrected reflectivity Z and differential reflectivity ZDR is just 1.0 and 0.19 dB, respectively. However, two data subsets reveal much larger discrepancies in Z (ZDR): 5.8 (1.6) dB in a hailstorm and −13 (−0.61) dB when the radar signal quality index (SQI) is less than 0.8. The discrepancies are much smaller when disdrometer and S-band Weather Surveillance Radar-1988 Doppler (WSR-88D) Z are compared, with differences of −1.5 dB (hailstorm) and −0.66 dB (NOXP SQI < 0.8). A comparison of the hydrometeor type retrieved from disdrometer and NOXP radar data is also presented, in which the same class is assigned 63% of the time.

Download Full-text

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.

Download Full-text

Integrated Correction Algorithm for X Band Dual-Polarization Radar Reflectivity Based on CINRAD/SA Radar

Atmosphere ◽

10.3390/atmos11010119 ◽

2020 ◽

Vol 11 (1) ◽

pp. 119

Author(s):

Chao Wang ◽

Chong Wu ◽

Liping Liu ◽

Xi Liu ◽

Chao Chen

Keyword(s):

Attenuation Correction ◽

Fixed Ratio ◽

Water Layer ◽

Resonance Scattering ◽

Rain Attenuation ◽

Correction Algorithm ◽

Dual Polarization ◽

Differential Phase ◽

X Band ◽

Ratio Correction

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.

Download Full-text

Attenuation correction for C-band radars using differential reflectivity

Tenth International Conference on Antennas and Propagation (ICAP) ◽

10.1049/cp:19970362 ◽

1997 ◽

Author(s):

J. Tan

Keyword(s):

Attenuation Correction ◽

Differential Reflectivity

Download Full-text

Can a Unique Model Describe the Raindrop Shape–Size Relation? A Clue from Polarimetric Radar Measurements

Journal of Atmospheric and Oceanic Technology ◽

10.1175/2009jtecha1183.1 ◽

2009 ◽

Vol 26 (9) ◽

pp. 1829-1842 ◽

Cited By ~ 9

Author(s):

Eugenio Gorgucci ◽

V. Chandrasekar ◽

Luca Baldini

Keyword(s):

Axial Ratio ◽

Radar Data ◽

Polarimetric Radar ◽

Drop Shape ◽

Climatic Regions ◽

Unique Shape ◽

Initial Drop ◽

Radar Measurements ◽

Differential Reflectivity ◽

Size Relation

Abstract A method is proposed to retrieve raindrop shape–size relations from the radar measurements of reflectivity factor Zh, differential reflectivity Zdr, and specific differential phase Kdp at S band. This procedure is obtained using a domain defined by the two variables Kdp/Zh and Zdr where the drop size distribution (DSD) variability is collapsed onto a line and any variation is essentially due to the drop shape variability. To obtain information on the raindrop shape–size relation underlying a set of radar observations, this domain is studied in conjunction with another domain describing the relation between the drop axial ratio (or shape) and its equivolumetric diameter. Using an initial drop shape and choosing a set of DSDs described by a normalized gamma model, polarimetric radar measurements are produced by simulation. An averaged curve of Kdp/Zh versus Zdr is obtained and compared with the same curve obtained from the radar data. By changing the initial axial ratio relation, a procedure of minimization between the two curves is developed to derive the underlying drop shape–size relation governing the radar measurements under consideration. Three sets of radar data collected in different climatic regions are analyzed to evaluate whether there is a unique shape–size relation.

Download Full-text