Cross Validation of TRMM PR Reflectivity Profiles Using 3D Reflectivity Composite from the Ground-Based Radar Network over the Korean Peninsula

Park, Shinju; Jung, Sung-Hwa; Lee, GyuWon

doi:10.1175/jhm-d-14-0092.1

Cited by 21 publications

(18 citation statements)

References 31 publications

(42 reference statements)

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“…Relative calibration (defined as the assessment of bias between the reflectivity of two radars) has been steadily gaining popularity, in particular the comparison with spaceborne precipitation radars (SR) (such as the precipitation radar onboard the Tropical Rainfall Measuring Mission (TRMM;1997Kummerow et al, 1998) and the dualfrequency precipitation radar on the subsequent Global Precipitation Measurement mission (GPM;2014-present;Hou et al, 2013)). Several studies have shown that surface precipitation estimates from GRs can be reliably compared to precipitation estimates from SRs for both TRMM (Amitai et al, 2009;Joss et al, 2006;Kirstetter et al, 2012) and GPM (Gabella et al, 2017;Petracca et al, 2018;Speirs et al, 2017). In addition, a major advantage of relative calibration and gauge adjustment in contrast to the absolute calibration (i.e.…”

Section: Introductionmentioning

confidence: 99%

Enhancing the consistency of spaceborne and ground-based radar comparisons by using beam blockage fraction as a quality filter

et al. 2018

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Abstract. We explore the potential of spaceborne radar (SR) observations from the Ku-band precipitation radars onboard the Tropical Rainfall Measuring Mission (TRMM) and Global Precipitation Measurement (GPM) satellites as a reference to quantify the ground radar (GR) reflectivity bias. To this end, the 3-D volume-matching algorithm proposed by Schwaller and Morris (2011) is implemented and applied to 5 years (2012–2016) of observations. We further extend the procedure by a framework to take into account the data quality of each ground radar bin. Through these methods, we are able to assign a quality index to each matching SR–GR volume, and thus compute the GR calibration bias as a quality-weighted average of reflectivity differences in any sample of matching GR–SR volumes. We exemplify the idea of quality-weighted averaging by using the beam blockage fraction as the basis of a quality index. As a result, we can increase the consistency of SR and GR observations, and thus the precision of calibration bias estimates. The remaining scatter between GR and SR reflectivity as well as the variability of bias estimates between overpass events indicate, however, that other error sources are not yet fully addressed. Still, our study provides a framework to introduce any other quality variables that are considered relevant in a specific context. The code that implements our analysis is based on the wradlib open-source software library, and is, together with the data, publicly available to monitor radar calibration or to scrutinize long series of archived radar data back to December 1997, when TRMM became operational.

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Section: Introductionmentioning

confidence: 99%

Enhancing the consistency of spaceborne and ground-based radar comparisons by using beam blockage fraction as a quality filter

et al. 2018

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“…However, we need to continue disentangling different sources of uncer-tainty for both SR and GR observations in order to distinguish actual variations in instrument calibration and stability from measurement errors that accumulate along the propagation path and to better understand the requirements for robustly estimating these properties from limited samples. This also includes extending the quality-weighting framework to the quality of SR reflectivity measurements, as already outlined in Crisologo et al (2018), particularly in regard to the combined effects of attenuation at Ku band and nonuniform beam filling that several authors found to cause systematic errors of SR reflectivity measurements in convective situations (see, e.g., Deo et al, 2018 andPark et al, 2015 for an in-depth discussion). Progress towards these ends should also improve the potential for interpolating calibration bias estimates in time, in order to tap into the potential of historical radar archives for radar climatology and increase the homogeneity of composite products from heterogeneous weather radar networks.…”

Section: Discussionmentioning

confidence: 99%

“…The main components of that workflow are based on the open-source software library for processing weather radar data called wradlib version 1.2 (Heistermann et al, 2013b) (released on 31 October 2018), based on Python 3.6. The main dependencies of wradlib include Numerical Python (NumPy; Oliphant, 2015), Matplotlib (Hunter, 2007), Scientific Python (SciPy; Virtanen et al, 2019), h5py (Collette, 2013), netCDF4 (Rew et al, 1989), gdal (GDAL Development Team, 2017), and pandas (McKinney, 2010).…”

Section: Computational Detailsmentioning

confidence: 99%

Using ground radar overlaps to verify the retrieval of calibration bias estimates from spaceborne platforms

Crisologo

Heistermann

2020

Atmos. Meas. Tech.

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Abstract. Many institutions struggle to tap into the potential of their large archives of radar reflectivity: these data are often affected by miscalibration, yet the bias is typically unknown and temporally volatile. Still, relative calibration techniques can be used to correct the measurements a posteriori. For that purpose, the usage of spaceborne reflectivity observations from the Tropical Rainfall Measuring Mission (TRMM) and Global Precipitation Measurement (GPM) platforms has become increasingly popular: the calibration bias of a ground radar (GR) is estimated from its average reflectivity difference to the spaceborne radar (SR). Recently, Crisologo et al. (2018) introduced a formal procedure to enhance the reliability of such estimates: each match between SR and GR observations is assigned a quality index, and the calibration bias is inferred as a quality-weighted average of the differences between SR and GR. The relevance of quality was exemplified for the Subic S-band radar in the Philippines, which is greatly affected by partial beam blockage. The present study extends the concept of quality-weighted averaging by accounting for path-integrated attenuation (PIA) in addition to beam blockage. This extension becomes vital for radars that operate at the C or X band. Correspondingly, the study setup includes a C-band radar that substantially overlaps with the S-band radar. Based on the extended quality-weighting approach, we retrieve, for each of the two ground radars, a time series of calibration bias estimates from suitable SR overpasses. As a result of applying these estimates to correct the ground radar observations, the consistency between the ground radars in the region of overlap increased substantially. Furthermore, we investigated if the bias estimates can be interpolated in time, so that ground radar observations can be corrected even in the absence of prompt SR overpasses. We found that a moving average approach was most suitable for that purpose, although limited by the absence of explicit records of radar maintenance operations.

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“…Gabella et al [32][33][34][35] designed range-dependent adjustment methods for the compensation of GR observations in consideration of the increasing sampling volume of the GR with range, and used this method to improve the rainfall estimation of the GR. Some recent studies made comparisons to evaluate the GR reflectivity in East Asia [36][37][38][39][40], in which stratiform precipitation was generally used to avoid uncertainties of PR products related to convective rain.…”

Section: Comparisons Of Reflectivity With Ground-based Radarsmentioning

confidence: 99%

Studies of General Precipitation Features with TRMM PR Data: An Extensive Overview

Wang

Chen

et al. 2019

Remote Sensing

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The Precipitation Radar (PR), the first space-borne precipitation radar onboard the Tropical Rainfall Measuring Mission (TRMM) satellite, could observe three-dimensional precipitation in global tropical regions and acquire continuous rainfall information with moderate temporal and high spatial resolutions. TRMM PR had carried out 17 years of observations and ended collecting data in April, 2015. So far, comprehensive and abundant research results related to the application of PR data have been analyzed in the current literature, but overall precipitation features are not yet identified, a gap that this review intends to fill. Studies on comparisons with ground-based radars and rain gauges are first introduced to summarize the reliability of PR observations or estimates. Then, this paper focuses on general precipitation features abstracted from about 130 studies, from 2000 to 2018, regarding lightning analysis, latent heat retrieval, and rainfall observation by PR data. Finally, we describe the existing problems and limitations as well as the future prospects of the space-borne precipitation radar data.

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Cross Validation of TRMM PR Reflectivity Profiles Using 3D Reflectivity Composite from the Ground-Based Radar Network over the Korean Peninsula

Cited by 21 publications

References 31 publications

Enhancing the consistency of spaceborne and ground-based radar comparisons by using beam blockage fraction as a quality filter

Enhancing the consistency of spaceborne and ground-based radar comparisons by using beam blockage fraction as a quality filter

Using ground radar overlaps to verify the retrieval of calibration bias estimates from spaceborne platforms

Studies of General Precipitation Features with TRMM PR Data: An Extensive Overview

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