The accuracy of weather radar in heavy rain: a comparative study for Denmark, the Netherlands, Finland and Sweden

Schleiss, Marc; Olsson, Jonas; Berg, Peter; Niemi, Tero; Kokkonen, Teemu; Thorndahl, Søren Liedtke; Nielsen, Rasmus Hjorth; Nielsen, Jesper Ellerbæk; Bozhinova, Denica; Pulkkinen, Seppo

doi:10.5194/hess-24-3157-2020

Cited by 57 publications

(54 citation statements)

References 101 publications

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“…Only about 0.3 percentage points of the MAP underestimation can be attributed to the radar gaps due to the reduced radius, so that there is quite a systematic negative bias in the data. Most other studies on radar-based QPE evaluations also revealed underestimations of precipitation totals [9,[53][54][55][56], but a few authors reported an overestimation [54,57]. However, such results are hard to compare due to large differences in radar hardware, correction algorithms and evaluation methods in the studies.…”

Section: Discussionmentioning

confidence: 93%

Radar-based Precipitation Climatology in Germany – Developments, Uncertainties and Potentials

Kreklow¹,

Tetzlaff²,

Burkhard³

et al. 2020

Preprint

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Precipitation is a crucial driver for many environmental processes and weather radars are capable of providing precipitation information with high spatial and temporal resolution. However, radar-based quantitative precipitation estimates (QPE) are also subject to various potential uncertainties. This study explores the development, uncertainties and potentials of the hourly operational German radar-based and gauge-adjusted QPE called RADOLAN and its reanalysed radar climatology dataset named RADKLIM in comparison to ground-truth rain gauge data. The precipitation datasets are statistically analysed across various time scales ranging from annual and seasonal aggregations to hourly rainfall intensities in regard to their capability to map long-term precipitation distribution, to detect low intensity rainfall and to capture heavy rainfall. Moreover, the impacts of season, orography and distance from the radar on long-term precipitation sums are examined in order to evaluate dataset performance and to describe inherent biases. Results revealed that both radar products tend to underestimate total precipitation sums and particularly high intensity rainfall. But our analyses also showed significant improvements throughout the RADOLAN time series as well as major advances through the climatologic reanalysis regarding the correction of typical radar artefacts, orographic and winter precipitation as well as range-dependent attenuation.

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Section: Discussionmentioning

confidence: 93%

Radar-based Precipitation Climatology in Germany – Developments, Uncertainties and Potentials

Kreklow¹,

Tetzlaff²,

Burkhard³

et al. 2020

Preprint

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“…Of course, the method is also sensitive to uncertainties hidden in radar data. The authors in [95] showed that radar precipitation estimates tend to underestimate intensive precipitation based on the evaluation of specific events in the territory of four different states. In the case of the proposed method, this means that it will underestimate the flash flooding hazard.…”

Section: Discussionmentioning

confidence: 99%

Dynamic Pluvial Flash Flooding Hazard Forecast Using Weather Radar Data

Rapant

Kolejka

2021

Remote Sensing

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Pluvial flash floods are among the most dangerous weather-triggered disasters, usually affecting watersheds smaller than 100 km2, with a short time to peak discharge (from a few minutes to a few hours) after causative rainfall. Several warning systems in the world try to use this time lag to predict the location, extent, intensity, and time of flash flooding. They are based on numerical hydrological models processing data collected by on-ground monitoring networks, weather radars, and precipitation nowcasting. However, there may be areas covered by weather radar data, in which the network of ground-based precipitation stations is not sufficiently developed or does not even exist (e.g., in an area covered by portable weather radar). We developed a method usable for designing an early warning system based on a different philosophy for such a situation. This method uses weather radar data as a 2D signal carrying information on the current precipitation distribution over the monitored area, and data on the watershed and drainage network in the area. The method transforms (concentrates) the 2D signal on precipitation distribution into a 1D signal carrying information on potential runoff distribution along the drainage network. For sections of watercourses where a significant increase in potential runoff can be expected (i.e., a significant increase of the 1D signal strength is detected), a warning against imminent flash floods can be possibly issued. The whole curve of the potential runoff development is not essential for issuing the alarm, but only the significant leading edge of the 1D signal is important. The advantage of this procedure is that results are obtained quickly and independent of any on-ground monitoring system; the disadvantage is that it does not provide the exact time of the onset of a flash flooding or its extent and intensity. The generated alert only warns that there is a higher flash flooding hazard in a specific section of the watercourse in the coming hours. The forecast is presented as a dynamic map of the flash flooding hazard distribution along the segments of watercourses. Relaying this hazard to segments of watercourses permits a substantial reduction in false alarms issued to not-endangered municipalities, which lie in safe areas far away from the watercourses. The method was tested at the local level (pluvial flash floods in two small regions of the Czech Republic) and the national level for rainfall episodes covering large areas in the Czech Republic. The conclusion was that the method is applicable at both levels. The results were compared mainly with data related to the Fire and Rescue Service interventions during floods. Finally, the increase in the reliability of hazard prediction using the information on soil saturation is demonstrated. The method is applicable in any region covered by a weather radar (e.g., a portable one), even if there are undeveloped networks of rain and hydrometric gauge stations. Further improvement could be achieved by processing more extended time series and using computational intelligence methods for classifying the degree of flash flooding hazard on individual sections of the watercourse network.

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“…It is possible to account for this spatial variability with geostatistical techniques (e.g., ordinary kriging, kriging with external drift or co-kriging; Krajewski, 1987;Creutin et al, 1988;Wackernagel, 2003;Schuurmans et al, 2007;Goudenhoofdt and Delobbe, 2009;Sideris et al, 2014) or Bayesian merging methods (Todini, 2001). Although these methods substantially improve the QPE in the spatial domain, all gauge-based radar QPE adjustment methods are limited by the timely availability of sufficient, and ideally qualitycontrolled, rain gauge observations (for an overview of methods and their limitations, see Ochoa-Rodriguez et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

A climatological benchmark for operational radar rainfall bias reduction

Imhoff

Brauer

Heeringen

et al. 2021

Hydrol. Earth Syst. Sci.

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Abstract. The presence of significant biases in real-time radar quantitative precipitation estimations (QPEs) limits its use in hydrometeorological forecasting systems. Here, we introduce CARROTS (Climatology-based Adjustments for Radar Rainfall in an OperaTional Setting), a set of fixed bias reduction factors, which vary per grid cell and day of the year. The factors are based on a historical set of 10 years of 5 min radar and reference rainfall data for the Netherlands. CARROTS is both operationally available and independent of real-time rain gauge availability and can thereby provide an alternative to current QPE adjustment practice. In addition, it can be used as benchmark for QPE algorithm development. We tested this method on the resulting rainfall estimates and discharge simulations for 12 Dutch catchments and polders. We validated the results against the operational mean field bias (MFB)-adjusted rainfall estimates and a reference dataset. This reference consists of the radar QPE, that combines an hourly MFB adjustment and a daily spatial adjustment using observations from 32 automatic and 319 manual rain gauges. Only the automatic gauges of this network are available in real time for the MFB adjustment. The resulting climatological correction factors show clear spatial and temporal patterns. Factors are higher away from the radars and higher from December through March than in other seasons, which is likely a result of sampling above the melting layer during the winter months. The MFB-adjusted QPE outperforms the CARROTS-corrected QPE when the country-average rainfall estimates are compared to the reference. However, annual rainfall sums from CARROTS are comparable to the reference and outperform the MFB-adjusted rainfall estimates for catchments away from the radars, where the MFB-adjusted QPE generally underestimates the rainfall amounts. This difference is absent for catchments closer to the radars. QPE underestimations are amplified when used in the hydrological model simulations. Discharge simulations using the QPE from CARROTS outperform those with the MFB-adjusted product for all but one basin. Moreover, the proposed factor derivation method is robust. It is hardly sensitive to leaving individual years out of the historical set and to the moving window length, given window sizes of more than a week.

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The accuracy of weather radar in heavy rain: a comparative study for Denmark, the Netherlands, Finland and Sweden

Cited by 57 publications

References 101 publications

Radar-based Precipitation Climatology in Germany – Developments, Uncertainties and Potentials

Radar-based Precipitation Climatology in Germany – Developments, Uncertainties and Potentials

Dynamic Pluvial Flash Flooding Hazard Forecast Using Weather Radar Data

A climatological benchmark for operational radar rainfall bias reduction

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The accuracy of weather radar in heavy rain: a comparative study for Denmark, the Netherlands, Finland and Sweden

Cited by 57 publications

References 101 publications

Radar-based Precipitation Climatology in Germany &ndash; Developments, Uncertainties and Potentials

Radar-based Precipitation Climatology in Germany &ndash; Developments, Uncertainties and Potentials

Dynamic Pluvial Flash Flooding Hazard Forecast Using Weather Radar Data

A climatological benchmark for operational radar rainfall bias reduction

Contact Info

Product

Resources

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Radar-based Precipitation Climatology in Germany – Developments, Uncertainties and Potentials

Radar-based Precipitation Climatology in Germany – Developments, Uncertainties and Potentials