Browsing by Author "Ahiataku, Maureen A."
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- ItemComparison of gauge rainfall measurements with TRMM satellite estimates over Kumasi(CCPOP, 2015-07-29) Amekudzi, Leonard K.; Osei, Marian A.; Ahiataku, Maureen A.; Oduro, Magaret A.; Asante-Bekoe, EugeneRainfall is an essential resource for socio-economic activities especially in developing countries. I Rainfall variability in Sub-Saharan Africa has been reported by Owusu et al. (2012), Nicholson et al. (2003), Amekudzi et al. (2015). I To improve our understanding of the spatio-temporal variations of rainfall rigourous validation has been carried out all over the world by comparing in-situ measurements with satellite estimates. (Friesen 2002; Amekudzi et al., 2011; Adeyewa and Nakamura 2003; Haque et al., 2013). I In the tropics, the Tropical Rainfall Measuring Mission (TRMM) has been specifically dedicated to monitoring rainfall intensity and distribution
- ItemValidation of TRMM and FEWS Satellite Rainfall Estimates with Rain Gauge Measurement over Ashanti Region, Ghana(Atmospheric and Climate Sciences, 2016-10-28) Amekudzi, Leonard K.; Osei, Marian A.; Atiah, Winifred A.; Aryee, Jeffrey N. A.; Ahiataku, Maureen A.; Quansah, Emmanuel; Preko, Kwasi; Danuor, Sylvester K.; Fink, Andreas H.Satellite rainfall estimates have predominantly been used for climate impact studies due to poor rain gauge network in sub-Saharan Africa. However, there are limited microscale studies within the sub-region that have assessed the performance of these satellite products, which is the focus of the present study. This paper therefore considers validation of Tropical Rainfall Measuring Mission (TRMM) and Famine Early Warning System (FEWS) satellite estimates with rain gauge measurements over Ashanti region of Ghana. First, a consistency assessment of the two gauge data products, the Automatic Rain Gauge (ARG) and Ghana Meteorological Agency (GMet) Standard Rain Gauge (SRG) measurements, was performed. This showed a very good agreement with correlation coefficient of 0.99. Secondly, satellite rainfall products from TRMM and FEWS were validated with the two gauge measurements. Validation results showed good agreement with correlation coefficients of 0.6 and 0.7 for TRMM and FEWS with SRG, and 0.87 and 0.86 for TRMM and FEWS with ARG respectively. Probability Of Detection (POD) and Volumetric Hit Index (VHI) were found to be greater than 0.9. Volumetric Critical Success Index (VCSI) was 0.9 and 0.8 for TRMM and FEWS respectively with low False Alarm Ratio (FAR) and insignificant Volumetric Miss Index (VMI). In general, relatively low biases and RMSE values were observed. The biases were less than 1.3 and 0.8 for TRMM and FEWSRFE respectively. These indicate high rainfall detection capabilities of both satellite products. In addition, both TRMM and FEWS were able to capture the onset, peak and cessation of the rainy season, as well as the dry spells. Although TRMM and FEWS sometimes under/overestimated rainfall, they have the potential to be used for agricultural and other hydro-climatic impact studies over the region. The Dynamic Aerosol-Cloud-Chemistry Interactions in West Africa (DACCIWA) project will provide an improved spatial gauge network database over the study area to enhance future validation and other climate impact studies.