Projecting future precipitation and temperature at sites with diverse climate through multiple statistical downscaling schemes
Anthropogenic-driven climate change would affect the global ecosystem and is becoming a world-wide concern. Numerous studies have been undertaken to determine the future trends of meteorological variables at different scales. Despite these studies, there remains significant uncertainty in the predic...
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sg-ntu-dr.10356-1385562020-05-08T04:32:00Z Projecting future precipitation and temperature at sites with diverse climate through multiple statistical downscaling schemes Vallam, Pramodh Qin, Xiao Sheng School of Civil and Environmental Engineering Environmental Process Modelling Centre Nanyang Environment and Water Research Institute Engineering::Environmental engineering Climate Change Bias Corrected Disaggregation Anthropogenic-driven climate change would affect the global ecosystem and is becoming a world-wide concern. Numerous studies have been undertaken to determine the future trends of meteorological variables at different scales. Despite these studies, there remains significant uncertainty in the prediction of future climates. To examine the uncertainty arising from using different schemes to downscale the meteorological variables for the future horizons, projections from different statistical downscaling schemes were examined. These schemes included statistical downscaling method (SDSM), change factor incorporated with LARS-WG, and bias corrected disaggregation (BCD) method. Global circulation models (GCMs) based on CMIP3 (HadCM3) and CMIP5 (CanESM2) were utilized to perturb the changes in the future climate. Five study sites (i.e., Alice Springs, Edmonton, Frankfurt, Miami, and Singapore) with diverse climatic conditions were chosen for examining the spatial variability of applying various statistical downscaling schemes. The study results indicated that the regions experiencing heavy precipitation intensities were most likely to demonstrate the divergence between the predictions from various statistical downscaling methods. Also, the variance computed in projecting the weather extremes indicated the uncertainty derived from selection of downscaling tools and climate models. This study could help gain an improved understanding about the features of different downscaling approaches and the overall downscaling uncertainty. MOE (Min. of Education, S’pore) 2020-05-08T04:32:00Z 2020-05-08T04:32:00Z 2017 Journal Article Vallam, P., & Qin, X. S. (2018). Projecting future precipitation and temperature at sites with diverse climate through multiple statistical downscaling schemes. Theoretical and Applied Climatology, 134(1-2), 669-688. doi:10.1007/s00704-017-2299-y 0177-798X https://hdl.handle.net/10356/138556 10.1007/s00704-017-2299-y 2-s2.0-85031912818 1-2 134 669 688 en Theoretical and Applied Climatology © 2017 Springer-Verlag GmbH Austria. All rights reserved. |
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Engineering::Environmental engineering Climate Change Bias Corrected Disaggregation Vallam, Pramodh Qin, Xiao Sheng Projecting future precipitation and temperature at sites with diverse climate through multiple statistical downscaling schemes |
| description |
Anthropogenic-driven climate change would affect the global ecosystem and is becoming a world-wide concern. Numerous studies have been undertaken to determine the future trends of meteorological variables at different scales. Despite these studies, there remains significant uncertainty in the prediction of future climates. To examine the uncertainty arising from using different schemes to downscale the meteorological variables for the future horizons, projections from different statistical downscaling schemes were examined. These schemes included statistical downscaling method (SDSM), change factor incorporated with LARS-WG, and bias corrected disaggregation (BCD) method. Global circulation models (GCMs) based on CMIP3 (HadCM3) and CMIP5 (CanESM2) were utilized to perturb the changes in the future climate. Five study sites (i.e., Alice Springs, Edmonton, Frankfurt, Miami, and Singapore) with diverse climatic conditions were chosen for examining the spatial variability of applying various statistical downscaling schemes. The study results indicated that the regions experiencing heavy precipitation intensities were most likely to demonstrate the divergence between the predictions from various statistical downscaling methods. Also, the variance computed in projecting the weather extremes indicated the uncertainty derived from selection of downscaling tools and climate models. This study could help gain an improved understanding about the features of different downscaling approaches and the overall downscaling uncertainty. |
| author2 |
School of Civil and Environmental Engineering |
| author_facet |
School of Civil and Environmental Engineering Vallam, Pramodh Qin, Xiao Sheng |
| format |
Article |
| author |
Vallam, Pramodh Qin, Xiao Sheng |
| author_sort |
Vallam, Pramodh |
| title |
Projecting future precipitation and temperature at sites with diverse climate through multiple statistical downscaling schemes |
| title_short |
Projecting future precipitation and temperature at sites with diverse climate through multiple statistical downscaling schemes |
| title_full |
Projecting future precipitation and temperature at sites with diverse climate through multiple statistical downscaling schemes |
| title_fullStr |
Projecting future precipitation and temperature at sites with diverse climate through multiple statistical downscaling schemes |
| title_full_unstemmed |
Projecting future precipitation and temperature at sites with diverse climate through multiple statistical downscaling schemes |
| title_sort |
projecting future precipitation and temperature at sites with diverse climate through multiple statistical downscaling schemes |
| publishDate |
2020 |
| url |
https://hdl.handle.net/10356/138556 |
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1681057326731100160 |