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The Florida Flood Hub for Applied Research and Innovation and the U.S. Geological Survey have developed projected future change factors for precipitation depth-duration-frequency (DDF) curves at 242 NOAA Atlas 14 stations in Florida. The change factors were computed as the ratio of projected future to historical extreme-precipitation depths fitted to extreme-precipitation data from downscaled climate datasets using a constrained maximum likelihood (CML) approach as described in https://doi.org/10.3133/sir20225093. The change factors correspond to the period 2020-59 (centered in the year 2040) as compared to the 1966-2005 historical period. A Microsoft Excel workbook is provided which tabulates quantiles of change...
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The Florida Flood Hub for Applied Research and Innovation and the U.S. Geological Survey have developed projected future change factors for precipitation depth-duration-frequency (DDF) curves at 242 NOAA Atlas 14 stations in Florida. The change factors were computed as the ratio of projected future to historical extreme-precipitation depths fitted to extreme-precipitation data from downscaled climate datasets using a constrained maximum likelihood (CML) approach as described in https://doi.org/10.3133/sir20225093. The change factors correspond to the period 2050-89 (centered in the year 2070) as compared to the 1966-2005 historical period. A Microsoft Excel workbook is provided which tabulates quantiles of change...
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The Florida Flood Hub for Applied Research and Innovation and the U.S. Geological Survey have developed projected future change factors for precipitation depth-duration-frequency (DDF) curves at 242 NOAA Atlas 14 stations in Florida. The change factors were computed as the ratio of projected future to historical extreme-precipitation depths fitted to extreme-precipitation data from downscaled climate datasets using a constrained maximum likelihood (CML) approach as described in https://doi.org/10.3133/sir20225093. The change factors correspond to the period 2050-89 (centered in the year 2070) as compared to the 1966-2005 historical period. A Microsoft Excel workbook is provided which tabulates quantiles of change...
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The Florida Flood Hub for Applied Research and Innovation and the U.S. Geological Survey have developed projected future change factors for precipitation depth-duration-frequency (DDF) curves at 242 NOAA Atlas 14 stations in Florida. The change factors were computed as the ratio of projected future to historical extreme-precipitation depths fitted to extreme-precipitation data from downscaled climate datasets using a constrained maximum likelihood (CML) approach as described in https://doi.org/10.3133/sir20225093. The change factors correspond to the period 2050-89 (centered in the year 2070) as compared to the 1966-2005 historical period. A Microsoft Excel workbook is provided which tabulates projected future...
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The Florida Flood Hub for Applied Research and Innovation and the U.S. Geological Survey have developed projected future change factors for precipitation depth-duration-frequency (DDF) curves at 242 NOAA Atlas 14 stations in Florida. The change factors were computed as the ratio of projected future to historical extreme-precipitation depths fitted to extreme-precipitation data from downscaled climate datasets using a constrained maximum likelihood (CML) approach as described in https://doi.org/10.3133/sir20225093. The change factors correspond to the period 2020-59 (centered in the year 2040) as compared to the 1966-2005 historical period. A Microsoft Excel workbook is provided which tabulates quantiles of change...
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The Florida Flood Hub for Applied Research and Innovation and the U.S. Geological Survey have developed projected future change factors for precipitation depth-duration-frequency (DDF) curves at 242 NOAA Atlas 14 stations in Florida. The change factors were computed as the ratio of projected future to historical extreme-precipitation depths fitted to extreme-precipitation data from downscaled climate datasets using a constrained maximum likelihood (CML) approach as described in https://doi.org/10.3133/sir20225093. The change factors correspond to the period 2020-59 (centered in the year 2040) as compared to the 1966-2005 historical period. A Microsoft Excel workbook is provided which tabulates quantiles of change...
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The Florida Flood Hub for Applied Research and Innovation and the U.S. Geological Survey have developed projected future change factors for precipitation depth-duration-frequency (DDF) curves at 242 NOAA Atlas 14 stations in Florida. The change factors were computed as the ratio of projected future to historical extreme-precipitation depths fitted to extreme-precipitation data from downscaled climate datasets using a constrained maximum likelihood (CML) approach as described in https://doi.org/10.3133/sir20225093. The change factors correspond to the period 2020-59 (centered in the year 2040) as compared to the 1966-2005 historical period. A Microsoft Excel workbook is provided which tabulates quantiles of change...
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The Florida Flood Hub for Applied Research and Innovation and the U.S. Geological Survey have developed projected future change factors for precipitation depth-duration-frequency (DDF) curves at 242 NOAA Atlas 14 stations in Florida. The change factors were computed as the ratio of projected future to historical extreme-precipitation depths fitted to extreme-precipitation data from downscaled climate datasets using a constrained maximum likelihood (CML) approach as described in https://doi.org/10.3133/sir20225093. The change factors correspond to the period 2020-59 (centered in the year 2040) as compared to the 1966-2005 historical period. A Microsoft Excel workbook is provided which tabulates quantiles of change...
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The Florida Flood Hub for Applied Research and Innovation and the U.S. Geological Survey have developed projected future change factors for precipitation depth-duration-frequency (DDF) curves at 242 NOAA Atlas 14 stations in Florida. The change factors were computed as the ratio of projected future to historical extreme-precipitation depths fitted to extreme-precipitation data from downscaled climate datasets using a constrained maximum likelihood (CML) approach as described in https://doi.org/10.3133/sir20225093. The change factors correspond to the period 2020-59 (centered in the year 2040) as compared to the 1966-2005 historical period. A Microsoft Excel workbook is provided which tabulates quantiles of change...
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The Florida Flood Hub for Applied Research and Innovation and the U.S. Geological Survey have developed projected future change factors for precipitation depth-duration-frequency (DDF) curves at 242 NOAA Atlas 14 stations in Florida. The change factors were computed as the ratio of projected future to historical extreme-precipitation depths fitted to extreme-precipitation data from downscaled climate datasets using a constrained maximum likelihood (CML) approach as described in https://doi.org/10.3133/sir20225093. The change factors correspond to the period 2050-89 (centered in the year 2070) as compared to the 1966-2005 historical period. A Microsoft Excel workbook is provided which tabulates quantiles of change...
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The Florida Flood Hub for Applied Research and Innovation and the U.S. Geological Survey have developed projected future change factors for precipitation depth-duration-frequency (DDF) curves at 242 National Oceanic and Atmospheric Administration (NOAA) Atlas 14 stations in Florida. The change factors were computed as the ratio of projected future to historical extreme-precipitation depths fitted to extreme-precipitation data from downscaled climate datasets using a constrained maximum likelihood (CML) approach as described in https://doi.org/10.3133/sir20225093. The change factors correspond to the periods 2020-59 (centered in the year 2040) and 2050-89 (centered in the year 2070) as compared to the 1966-2005 historical...
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The Florida Flood Hub for Applied Research and Innovation and the U.S. Geological Survey have developed projected future change factors for precipitation depth-duration-frequency (DDF) curves at 242 NOAA Atlas 14 stations in Florida. The change factors were computed as the ratio of projected future to historical extreme-precipitation depths fitted to extreme-precipitation data from downscaled climate datasets using a constrained maximum likelihood (CML) approach as described in https://doi.org/10.3133/sir20225093. The change factors correspond to the period 2050-89 (centered in the year 2070) as compared to the 1966-2005 historical period. A Microsoft Excel workbook is provided which tabulates quantiles of change...
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The Florida Flood Hub for Applied Research and Innovation and the U.S. Geological Survey have developed projected future change factors for precipitation depth-duration-frequency (DDF) curves at 242 National Oceanic and Atmospheric Administration (NOAA) Atlas 14 stations in Florida. The change factors were computed as the ratio of projected future to historical extreme-precipitation depths fitted to extreme-precipitation data from downscaled climate datasets using a constrained maximum likelihood (CML) approach as described in https://doi.org/10.3133/sir20225093. The change factors correspond to the period 2020-59 (centered in 2040) or to the period 2050-89 (centered in the year 2070) as compared to the 1966-2005...
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The Florida Flood Hub for Applied Research and Innovation and the U.S. Geological Survey have developed projected future change factors for precipitation depth-duration-frequency (DDF) curves at 242 National Oceanic and Atmospheric Administration (NOAA) Atlas 14 stations in Florida. The change factors were computed as the ratio of projected future to historical extreme-precipitation depths fitted to extreme-precipitation data from downscaled climate datasets using a constrained maximum likelihood (CML) approach as described in https://doi.org/10.3133/sir20225093. The change factors correspond to the periods 2020-59 (centered in the year 2040) and 2050-89 (centered in the year 2070) as compared to the 1966-2005 historical...
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The Florida Flood Hub for Applied Research and Innovation and the U.S. Geological Survey have developed projected future change factors for precipitation depth-duration-frequency (DDF) curves at 242 NOAA Atlas 14 stations in Florida. The change factors were computed as the ratio of projected future to historical extreme-precipitation depths fitted to extreme-precipitation data from downscaled climate datasets using a constrained maximum likelihood (CML) approach as described in https://doi.org/10.3133/sir20225093. The change factors correspond to the period 2020-59 (centered in the year 2040) as compared to the 1966-2005 historical period. A Microsoft Excel workbook is provided which tabulates quantiles of change...
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The Florida Flood Hub for Applied Research and Innovation and the U.S. Geological Survey have developed projected future change factors for precipitation depth-duration-frequency (DDF) curves at 242 NOAA Atlas 14 stations in Florida. The change factors were computed as the ratio of projected future to historical extreme-precipitation depths fitted to extreme-precipitation data from downscaled climate datasets using a constrained maximum likelihood (CML) approach as described in https://doi.org/10.3133/sir20225093. The change factors correspond to the period 2020-59 (centered in the year 2040) as compared to the 1966-2005 historical period. A Microsoft Excel workbook is provided which tabulates quantiles of change...
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The Florida Flood Hub for Applied Research and Innovation and the U.S. Geological Survey have developed projected future change factors for precipitation depth-duration-frequency (DDF) curves at 242 NOAA Atlas 14 stations in Florida. The change factors were computed as the ratio of projected future to historical extreme-precipitation depths fitted to extreme-precipitation data from downscaled climate datasets using a constrained maximum likelihood (CML) approach as described in https://doi.org/10.3133/sir20225093. The change factors correspond to the period 2050-89 (centered in the year 2070) as compared to the 1966-2005 historical period. A Microsoft Excel workbook is provided which tabulates quantiles of change...
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The Florida Flood Hub for Applied Research and Innovation and the U.S. Geological Survey have developed projected future change factors for precipitation depth-duration-frequency (DDF) curves at 242 National Oceanic and Atmospheric Administration (NOAA) Atlas 14 stations in Florida. The change factors were computed as the ratio of projected future to historical extreme-precipitation depths fitted to extreme-precipitation data from downscaled climate datasets using a constrained maximum likelihood (CML) approach as described in https://doi.org/10.3133/sir20225093. The change factors correspond to the periods 2020-59 (centered in the year 2040) and 2050-89 (centered in the year 2070) as compared to the 1966-2005 historical...
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The Florida Flood Hub for Applied Research and Innovation and the U.S. Geological Survey have developed projected future change factors for precipitation depth-duration-frequency (DDF) curves at 242 NOAA Atlas 14 stations in Florida. The change factors were computed as the ratio of projected future to historical extreme-precipitation depths fitted to extreme-precipitation data from downscaled climate datasets using a constrained maximum likelihood (CML) approach as described in https://doi.org/10.3133/sir20225093. The change factors correspond to the period 2038-42 (centered in the year 2040) as compared to the 1966-2005 historical period. A Microsoft Excel workbook is provided which tabulates projected future...
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The Florida Flood Hub for Applied Research and Innovation and the U.S. Geological Survey have developed projected future change factors for precipitation depth-duration-frequency (DDF) curves at 242 NOAA Atlas 14 stations in Florida. The change factors were computed as the ratio of projected future to historical extreme-precipitation depths fitted to extreme-precipitation data from downscaled climate datasets using a constrained maximum likelihood (CML) approach as described in https://doi.org/10.3133/sir20225093. The change factors correspond to the periods 2020-59 (centered in the year 2040), and 2050-89 (centeredin the year 2070) as compared to the 1966-2005 historical period. A Microsoft Excel workbook is provided...
map background search result map search result map Spreadsheet of areal reduction factors by region in Florida (Areal_reduction_factors.xlsx) Spreadsheet of quantiles of change factors at 242 NOAA Atlas 14 stations in Florida derived from downscaled climate datasets considering only the best models and all future emission scenarios evaluated (CFquantiles_2040_to_historical_best_models_allRCPs.xlsx) Spreadsheet of quantiles of change factors at 242 NOAA Atlas 14 stations in Florida derived from downscaled climate datasets considering all models, and the RCP4.5 and SSP2-4.5 future emission scenarios (CFquantiles_2070_to_historical_all_models_RCP4.5.xlsx) Spreadsheet of quantiles of change factors at 242 NOAA Atlas 14 stations in Florida derived from downscaled climate datasets considering all models, and the RCP8.5 and SSP5-8.5 future emission scenarios (CFquantiles_2070_to_historical_all_models_RCP8.5.xlsx) Spreadsheet of projected future precipitation depths at 170 NOAA Atlas 14 stations in Florida fitted to extreme-precipitation events derived from the Analog Resampling and Statistical Scaling Method by Jupiter Intelligence using the Weather Research and Forecasting Model (JupiterWRF) downscaled climate dataset (DDF_JupiterWRF_future_2040.xlsx) Spreadsheet of projected future precipitation depths at 242 NOAA Atlas 14 stations in Florida fitted to extreme-precipitation events derived from the MACA downscaled climate dataset (DDF_MACA_future_2070.xlsx) R script to create boxplots of change factors by NOAA Atlas 14 station, or for all stations in a Florida HUC-8 basin or county (create_boxplot.R) Shapefile of Areal Reduction Factor (ARF) regions for the state of Florida (ARF_regions.shp) Spreadsheet of quantiles of change factors at 242 NOAA Atlas 14 stations in Florida derived from CMIP6 downscaled climate datasets considering all models and all future emission scenarios evaluated (CFquantiles_2040_to_historical_allmodels_allSSPs_CMIP6.xlsx). Spreadsheet of quantiles of change factors at 242 NOAA Atlas 14 stations in Florida derived from CMIP6 downscaled climate datasets considering all models, and the SSP1-2.6 future emissions scenario scenario(CFquantiles_2040_to_historical_allmodels_SSP1-2.6_CMIP6.xlsx). Spreadsheet of quantiles of change factors at 242 NOAA Atlas 14 stations in Florida derived from CMIP6 downscaled climate datasets considering all models, and the SSP2-4.5 future emissions scenario scenario(CFquantiles_2040_to_historical_allmodels_SSP2-4.5_CMIP6.xlsx). Spreadsheet of quantiles of change factors at 242 NOAA Atlas 14 stations in Florida derived from CMIP6 downscaled climate datasets considering all models, and the SSP3-7.0 future emissions scenario scenario(CFquantiles_2040_to_historical_allmodels_SSP3-7.0_CMIP6.xlsx). Spreadsheet of quantiles of change factors at 242 NOAA Atlas 14 stations in Florida derived from CMIP6 downscaled climate datasets considering only the best models, and all future emission scenarios evaluated (CFquantiles_2040_to_historical_allmodels_allSSPs_CMIP6.xlsx). Spreadsheet of quantiles of change factors at 242 NOAA Atlas 14 stations in Florida derived from CMIP6 downscaled climate datasets considering only the best models, and the SSP3-7.0 future emissions scenario (CFquantiles_2040_to_historical_allmodels_SSP3-7.0_CMIP6.xlsx). Spreadsheet of quantiles of change factors at 242 NOAA Atlas 14 stations in Florida derived from CMIP6 downscaled climate datasets considering only the best models, and the SSP5-8.5 future emissions scenario (CFquantiles_2040_to_historical_allmodels_SSP5-8.5_CMIP6.xlsx). Spreadsheet of quantiles of change factors at 242 NOAA Atlas 14 stations in Florida derived from CMIP6 downscaled climate datasets considering all models and all future emission scenarios evaluated (CFquantiles_2070_to_historical_allmodels_allSSPs_CMIP6.xlsx). Spreadsheet of quantiles of change factors at 242 NOAA Atlas 14 stations in Florida derived from CMIP6 downscaled climate datasets considering all models, and the SSP1-2.6 future emissions scenario scenario(CFquantiles_2070_to_historical_allmodels_SSP1-2.6_CMIP6.xlsx). Spreadsheet of quantiles of change factors at 242 NOAA Atlas 14 stations in Florida derived from CMIP6 downscaled climate datasets considering only the best models, and all future emission scenarios evaluated (CFquantiles_2070_to_historical_allmodels_allSSPs_CMIP6.xlsx). Spreadsheet of historical precipitation depths at 242 NOAA Atlas 14 stations in Florida fitted to extreme-precipitation events derived from the NASA downscaled climate dataset (DDF_NASA_historical.xlsx) Spreadsheet of best models for each CMIP5 downscaled climate dataset and for all downscaled climate datasets considered together (Best_model_lists.xlsx) Spreadsheet of areal reduction factors by region in Florida (Areal_reduction_factors.xlsx) Spreadsheet of quantiles of change factors at 242 NOAA Atlas 14 stations in Florida derived from downscaled climate datasets considering only the best models and all future emission scenarios evaluated (CFquantiles_2040_to_historical_best_models_allRCPs.xlsx) Spreadsheet of quantiles of change factors at 242 NOAA Atlas 14 stations in Florida derived from downscaled climate datasets considering all models, and the RCP4.5 and SSP2-4.5 future emission scenarios (CFquantiles_2070_to_historical_all_models_RCP4.5.xlsx) Spreadsheet of quantiles of change factors at 242 NOAA Atlas 14 stations in Florida derived from downscaled climate datasets considering all models, and the RCP8.5 and SSP5-8.5 future emission scenarios (CFquantiles_2070_to_historical_all_models_RCP8.5.xlsx) Spreadsheet of projected future precipitation depths at 170 NOAA Atlas 14 stations in Florida fitted to extreme-precipitation events derived from the Analog Resampling and Statistical Scaling Method by Jupiter Intelligence using the Weather Research and Forecasting Model (JupiterWRF) downscaled climate dataset (DDF_JupiterWRF_future_2040.xlsx) Spreadsheet of projected future precipitation depths at 242 NOAA Atlas 14 stations in Florida fitted to extreme-precipitation events derived from the MACA downscaled climate dataset (DDF_MACA_future_2070.xlsx) R script to create boxplots of change factors by NOAA Atlas 14 station, or for all stations in a Florida HUC-8 basin or county (create_boxplot.R) Spreadsheet of quantiles of change factors at 242 NOAA Atlas 14 stations in Florida derived from CMIP6 downscaled climate datasets considering all models and all future emission scenarios evaluated (CFquantiles_2040_to_historical_allmodels_allSSPs_CMIP6.xlsx). Spreadsheet of quantiles of change factors at 242 NOAA Atlas 14 stations in Florida derived from CMIP6 downscaled climate datasets considering all models, and the SSP1-2.6 future emissions scenario scenario(CFquantiles_2040_to_historical_allmodels_SSP1-2.6_CMIP6.xlsx). Spreadsheet of quantiles of change factors at 242 NOAA Atlas 14 stations in Florida derived from CMIP6 downscaled climate datasets considering all models, and the SSP2-4.5 future emissions scenario scenario(CFquantiles_2040_to_historical_allmodels_SSP2-4.5_CMIP6.xlsx). Spreadsheet of quantiles of change factors at 242 NOAA Atlas 14 stations in Florida derived from CMIP6 downscaled climate datasets considering all models, and the SSP3-7.0 future emissions scenario scenario(CFquantiles_2040_to_historical_allmodels_SSP3-7.0_CMIP6.xlsx). Spreadsheet of quantiles of change factors at 242 NOAA Atlas 14 stations in Florida derived from CMIP6 downscaled climate datasets considering only the best models, and all future emission scenarios evaluated (CFquantiles_2040_to_historical_allmodels_allSSPs_CMIP6.xlsx). Spreadsheet of quantiles of change factors at 242 NOAA Atlas 14 stations in Florida derived from CMIP6 downscaled climate datasets considering only the best models, and the SSP3-7.0 future emissions scenario (CFquantiles_2040_to_historical_allmodels_SSP3-7.0_CMIP6.xlsx). Spreadsheet of quantiles of change factors at 242 NOAA Atlas 14 stations in Florida derived from CMIP6 downscaled climate datasets considering only the best models, and the SSP5-8.5 future emissions scenario (CFquantiles_2040_to_historical_allmodels_SSP5-8.5_CMIP6.xlsx). Spreadsheet of quantiles of change factors at 242 NOAA Atlas 14 stations in Florida derived from CMIP6 downscaled climate datasets considering all models and all future emission scenarios evaluated (CFquantiles_2070_to_historical_allmodels_allSSPs_CMIP6.xlsx). Spreadsheet of quantiles of change factors at 242 NOAA Atlas 14 stations in Florida derived from CMIP6 downscaled climate datasets considering all models, and the SSP1-2.6 future emissions scenario scenario(CFquantiles_2070_to_historical_allmodels_SSP1-2.6_CMIP6.xlsx). Spreadsheet of quantiles of change factors at 242 NOAA Atlas 14 stations in Florida derived from CMIP6 downscaled climate datasets considering only the best models, and all future emission scenarios evaluated (CFquantiles_2070_to_historical_allmodels_allSSPs_CMIP6.xlsx). Spreadsheet of historical precipitation depths at 242 NOAA Atlas 14 stations in Florida fitted to extreme-precipitation events derived from the NASA downscaled climate dataset (DDF_NASA_historical.xlsx) Spreadsheet of best models for each CMIP5 downscaled climate dataset and for all downscaled climate datasets considered together (Best_model_lists.xlsx) Shapefile of Areal Reduction Factor (ARF) regions for the state of Florida (ARF_regions.shp)