Combined use of satellite estimates and rain gauge observations to generate high‐quality historical rainfall time series over Ethiopia

Dinku, Tufa; Hailemariam, Kinfe; Maidment, Ross; Tarnavsky, Elena; Connor, Stephen J.

doi:10.1002/joc.3855

Cited by 166 publications

(134 citation statements)

References 23 publications

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“…At present, the combination of short record lengths and highly uncertain precipitation intensities during storm events make it difficult to recommend the use of rainfall-driven model cascades to estimate fluvial flood risk, especially where estimates of return period are necessary. Looking forward, increased resolution regional reanalysis products with improved rainfall process representation may help to reduce these uncertainties as may the assimilation of local data into global observational data sets to produce improved regional calibrations for rainfall products (Dinku et al, 2013). Further effort should also be concentrated on developing alternative means of characterising the loss-driving properties of river basins.…”

Section: Discussionmentioning

confidence: 99%

The impact of uncertain precipitation data on insurance loss estimates using a flood catastrophe model

Sampson

Fewtrell²,

O’Loughlin

et al. 2014

Hydrol. Earth Syst. Sci.

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Abstract. Catastrophe risk models used by the insurance industry are likely subject to significant uncertainty, but due to their proprietary nature and strict licensing conditions they are not available for experimentation. In addition, even if such experiments were conducted, these would not be repeatable by other researchers because commercial confidentiality issues prevent the details of proprietary catastrophe model structures from being described in public domain documents. However, such experimentation is urgently required to improve decision making in both insurance and reinsurance markets. In this paper we therefore construct our own catastrophe risk model for flooding in Dublin, Ireland, in order to assess the impact of typical precipitation data uncertainty on loss predictions. As we consider only a city region rather than a whole territory and have access to detailed data and computing resources typically unavailable to industry modellers, our model is significantly more detailed than most commercial products. The model consists of four components, a stochastic rainfall module, a hydrological and hydraulic flood hazard module, a vulnerability module, and a financial loss module. Using these we undertake a series of simulations to test the impact of driving the stochastic event generator with four different rainfall data sets: ground gauge data, gauge-corrected rainfall radar, meteorological reanalysis data (European Centre for MediumRange Weather Forecasts Reanalysis-Interim; ERA-Interim) and a satellite rainfall product (The Climate Prediction Center morphing method; CMORPH). Catastrophe models are unusual because they use the upper three components of the modelling chain to generate a large synthetic database of unobserved and severe loss-driving events for which estimated losses are calculated. We find the loss estimates to be more sensitive to uncertainties propagated from the driving precipitation data sets than to other uncertainties in the hazard and vulnerability modules, suggesting that the range of uncertainty within catastrophe model structures may be greater than commonly believed.

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Section: Discussionmentioning

confidence: 99%

The impact of uncertain precipitation data on insurance loss estimates using a flood catastrophe model

Sampson

Fewtrell²,

O’Loughlin

et al. 2014

Hydrol. Earth Syst. Sci.

View full text Add to dashboard Cite

show abstract

“…The available gauge stations are unevenly distributed and sparse as seen in Figure 1, this usually brings a limitation to the quality of data. To overcome this limitation, satellite proxies particularly rainfall estimates are better used as alternatives because of their availability even over remote areas [9,10]. There were gaps in the gauge observation when compared to widespread heavy rainfall on satellite estimate ( Figure 2).…”

Section: Methodsmentioning

confidence: 99%

Evaluation of Selected Numerical Weather Prediction Models for a Case of Widespread Rainfall over Central and Southern Nigeria

Agogbuo¹,

Nwagbara²,

Bekele³

et al. 2017

J Environ Anal Toxicol

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“…The bias adjustment is based on a previous study carried in Ethiopia [35]. First of all, the satellite rainfall estimates are extracted at rain gauge locations.…”

Section: Residual Inverse Distance Weighting (Ridw)mentioning

confidence: 99%

Satellite Rainfall (TRMM 3B42-V7) Performance Assessment and Adjustment over Pahang River Basin, Malaysia

2018

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Abstract:The Tropical Rainfall Measuring Mission (TRMM) was the first Earth Science mission dedicated to studying tropical and subtropical rainfall. Up until now, there is still limited knowledge on the accuracy of the version 7 research product TRMM 3B42-V7 despite having the advantage of a high temporal resolution and large spatial coverage over oceans and land. This is particularly the case in tropical regions in Asia. The objective of this study is therefore to analyze the performance of rainfall estimation from TRMM 3B42-V7 (henceforth TRMM) using rain gauge data in Malaysia, specifically from the Pahang river basin as a case study, and using a set of performance indicators/scores. The results suggest that the altitude of the region affects the performances of the scores. Root Mean Squared Error (RMSE) is lower mostly at a higher altitude and mid-altitude. The correlation coefficient (CC) generally shows a positive but weak relationship between the rain gauge measurements and TRMM (0 < CC < 0.4), while the Nash-Sutcliffe Efficiency (NSE) scores are low (NSE < 0.1). The Percent Bias (PBIAS) shows that TRMM tends to overestimate the rainfall measurement by 26.95% on average. The Probability of Detection (POD) and Threat Score (TS) demonstrate that more than half of the pixel-point pairs have values smaller than 0.7. However, the Probability of False Detection (POFD) and False Alarm Rate (FAR) show that most of the pixel-point gauges have values lower than 0.55. The seasonal analysis shows that TRMM overestimates during the wet season and underestimates during the dry season. The bias adjustment shows that Mean Bias Correction (MBC) improved the scores better than Double-Kernel Residual Smoothing (DS) and Residual Inverse Distance Weighting (RIDW). The large errors imply that TRMM may not be suitable for applications in environmental, water resources, and ecological studies without prior correction.

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Combined use of satellite estimates and rain gauge observations to generate high‐quality historical rainfall time series over Ethiopia

Cited by 166 publications

References 23 publications

The impact of uncertain precipitation data on insurance loss estimates using a flood catastrophe model

The impact of uncertain precipitation data on insurance loss estimates using a flood catastrophe model

Evaluation of Selected Numerical Weather Prediction Models for a Case of Widespread Rainfall over Central and Southern Nigeria

Satellite Rainfall (TRMM 3B42-V7) Performance Assessment and Adjustment over Pahang River Basin, Malaysia

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