Enhanced radar precipitation estimates using a combined clutter and beam  blockage correction technique

Fornasiero, A.; Bech, Joan; Alberoni, P. P.

doi:10.5194/nhess-6-697-2006

Cited by 22 publications

(16 citation statements)

References 23 publications

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“…In literature, multiple GC identification techniques have been proposed, using either pulse to pulse reflectivity fluctuations [ Wessels and Beekhuis , 1994], radial Doppler velocity information [ Joss and Lee , 1995], spatial reflectivity information [ Alberoni et al , 2001], or dual‐polarization data [ Giuli et al , 1991]. Other sources of data have also been used to identify GC, such as digital elevation models, temperature, or satellite information [e.g., Delrieu et al , 1995; Michelson and Sunhede , 2004; Fornasiero et al , 2006]. Currently, most GC identification algorithms make use of a classification scheme using multiple information criteria [e.g., Joss and Pittini , 1991; Joss and Lee , 1995; Steiner and Smith , 2002; Grecu and Krajewski , 2000; Berenguer et al , 2006; Cho et al , 2006].…”

Section: Radar Reflectivity Analysismentioning

confidence: 99%

Radar rainfall estimation of stratiform winter precipitation in the Belgian Ardennes

Hazenberg

Leijnse

Uijlenhoet

2011

Water Resources Research

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[1] Radars are known for their ability to obtain a wealth of information about spatial storm field characteristics. Unfortunately, rainfall estimates obtained by this instrument are known to be affected by multiple sources of error. Especially for stratiform precipitation systems, the quality of radar rainfall estimates starts to decrease at relatively close ranges. In the current study, the hydrological potential of weather radar is analyzed during a winter halfyear for the hilly region of the Belgian Ardennes. A correction algorithm is proposed which corrects the radar data for errors related to attenuation, ground clutter, anomalous propagation, the vertical profile of reflectivity (VPR), and advection. No final bias correction with respect to rain gauge data was implemented because such an adjustment would not add to a better understanding of the quality of the radar data. The impact of the different corrections is assessed using rainfall information sampled by 42 hourly rain gauges. The largest improvement in the quality of the radar data is obtained by correcting for ground clutter. The impact of VPR correction and advection depends on the spatial variability and velocity of the precipitation system. Overall during the winter period, the radar underestimates the amount of precipitation as compared to the rain gauges. Remaining differences between both instruments can be attributed to spatial and temporal variability in the type of precipitation, which has not been taken into account.Citation: Hazenberg, P., H. Leijnse, and R. Uijlenhoet (2011), Radar rainfall estimation of stratiform winter precipitation in the

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Section: Radar Reflectivity Analysismentioning

confidence: 99%

Radar rainfall estimation of stratiform winter precipitation in the Belgian Ardennes

Hazenberg

Leijnse

Uijlenhoet

2011

Water Resources Research

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“…Then, a 2D dynamic map is constructed for each pixel, taking into account the beam trajectory simulated using the vertical profiles from radio soundings. By adopting these information, the mean clutter should be avoided and the beam blockage reduced to values lower than 50 % (Bech et al 2003;Fornasiero 2006;Fornasiero et al 2006).…”

Section: Radarmentioning

confidence: 99%

Comparison of spectral characteristics of precipitation from radar estimates and COSMO-model predicted fields

Willeit

Amorati

Montani

et al. 2014

Meteorol Atmos Phys

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The spectral characteristics of hourly precipitation fields are studied for a number of meteorological events, classified depending on the precipitation process involved, namely stratiform, convective or mixed stratiform-convective. The study focuses on the comparison between spatial spectral characteristics of observed precipitation fields, obtained from hourly radar estimates, and modelled hourly predictions of the same field by the nonhydrostatic model COSMO. The results show that the power spectra of radar hourly precipitation are characterised by invariance within ranges of horizontal spatial scales that are different for the three classes of events. COSMO reproduces some basic characteristics of the radar spectra in all cases. Nevertheless, in stratiform events, COSMO spectra present a well-defined scale break at about 15 km with no counterpart in radar data. It is suggested that this model feature is related to the presence of spurious horizontal smoothing introduced by the semi-lagrangian advection scheme for precipitation. Smoothing affects all scales up to the maximum length scale of precipitation and horizontal advection by the wind. An analysis of wind intensity in the lower troposphere over the region supports this interpretation. Discrepancies in precipitation spectra between radar and COSMO data in convective events are interpreted as a consequence of the inadequacy of the model resolution for a correct representation of convection.

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“…However, various studies have revealed that estimating precipitation from radar also poses significant problems; electronic miscalibration (Goudenhoofdt and Delobbe, 2009), signal contamination by non-meteorological echoes or range effect (Fries et al, 2014), beam blocking by natural impediments (e.g. mountain region, surrounding hills with similar or higher altitudes) and the variance in the reflectivity and rainfall rate relationships (Jameson and Kostinski, 2002;Fornasiero et al, 2006;Vulpiani et al, 2012;Yoon and Bae, 2013;Lim et al, 2014;Qin et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

Geospatial blending to improve spatial mapping of precipitation with high spatial resolution by merging satellite-based and ground-based data

et al. 2016

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Abstract:Estimating accurate spatial distribution of precipitation is important for understanding the hydrologic cycle and various hydroenvironmental applications. Satellite-based precipitation data have been widely used to measure the spatial distribution of precipitation over large extents, but an improvement in accuracy is still needed. In this study, three different merging techniques (Conditional Merging, Geographical Differential Analysis and Geographical Ratio Analysis) were used to merge precipitation estimations from Communication, Ocean and Meteorological Satellite (COMS) Rainfall Intensity data and ground-based measurements. Merged products were evaluated with varying rain-gauge network densities and accumulation times. The results confirmed that accuracy of detecting quantitative rainfall was improved as the accumulation time and network density increased. Also, the impact of spatial heterogeneity of precipitation on the merged estimates was investigated. Our merging techniques reproduced accurate spatial distribution of rainfall by adopting the advantages of both gauge and COMS estimates. The efficacy of the merging techniques was particularly pronounced when the spatial heterogeneity of hourly rainfall, quantified by variance of rainfall, was greater than 10 mm 2 /accumulation time 2 . Among the techniques analysed, Conditional Merging performed the best, especially when the gauge density was low. This study demonstrates the utility of the COMS Rainfall Intensity product, which has a shorter latency time (1 h) and higher spatio-temporal resolution (hourly, 4 km by 4 km) than other widely used satellite precipitation products in estimating precipitation using merging techniques with ground-based point measurements. The outcome has important implications for various hydrologic modelling approaches, especially for producing near real-time products.

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Enhanced radar precipitation estimates using a combined clutter and beam blockage correction technique

Cited by 22 publications

References 23 publications

Radar rainfall estimation of stratiform winter precipitation in the Belgian Ardennes

Radar rainfall estimation of stratiform winter precipitation in the Belgian Ardennes

Comparison of spectral characteristics of precipitation from radar estimates and COSMO-model predicted fields

Geospatial blending to improve spatial mapping of precipitation with high spatial resolution by merging satellite-based and ground-based data

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