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Drought hazard SMA 25-year return period - SSP5 Upper bound
Drought Hazard map based on the SMA-1 indicator (Standardised Moisture Anomaly cumulated on a 1-month window). The map refers to the return period RT = 25 Years and it is computated on the basis of exceeding the SMA-1 value of one Sigma in each pixel of the analyised domain for a duration of at least 3 consecutive months using SSP5 Upper bound Climate change scenario.
The existing climate refers to the entire historical period of the last 40 years (1979 - 2016) the methodology employed for the computation is exhaustively explained in the Background paper.
There are reference periods for the existing climate and for the future scenarios the average duration is computed over such periods in a statistical sense (for future years from 2060 to 2100 are considered). The definition of the indicator is a series of consecutive days where the used indicator is below -1. Read More
The existing climate refers to the entire historical period of the last 40 years (1979 - 2016) the methodology employed for the computation is exhaustively explained in the Background paper.
There are reference periods for the existing climate and for the future scenarios the average duration is computed over such periods in a statistical sense (for future years from 2060 to 2100 are considered). The definition of the indicator is a series of consecutive days where the used indicator is below -1. Read More
Drought hazard SMA 5-year return period - Existing climate
Drought Hazard map based on the SMA-1 indicator (Standardised Moisture Anomaly cumulated on a 1-month window). The map refers to the return period RT = 5 Years and it is computated on the basis of exceeding the SMA-1 value of one Sigma in each pixel of the analyised domain for a duration of at least 3 consecutive months.
The existing climate refers to the entire historical period of the last 40 years (1979 - 2016) the methodology employed for the computation is exhaustively explained in the Background paper.
There are reference periods for the existing climate and for the future scenarios the average duration is computed over such periods in a statistical sense (for future years from 2060 to 2100 are considered). The definition of the indicator is a series of consecutive days where the used indicator is below -1. Read More
The existing climate refers to the entire historical period of the last 40 years (1979 - 2016) the methodology employed for the computation is exhaustively explained in the Background paper.
There are reference periods for the existing climate and for the future scenarios the average duration is computed over such periods in a statistical sense (for future years from 2060 to 2100 are considered). The definition of the indicator is a series of consecutive days where the used indicator is below -1. Read More
Drought hazard SMA 5-year return period - SSP1 Lower bound
Drought Hazard map based on the SMA-1 indicator (Standardised Moisture Anomaly cumulated on a 1-month window). The map refers to the return period RT = 5 Years and it is computated on the basis of exceeding the SMA-1 value of one Sigma in each pixel of the analyised domain for a duration of at least 3 consecutive months using SSP1 Lower bound Climate change scenario.
The existing climate refers to the entire historical period of the last 40 years (1979 - 2016) the methodology employed for the computation is exhaustively explained in the Background paper.
There are reference periods for the existing climate and for the future scenarios the average duration is computed over such periods in a statistical sense (for future years from 2060 to 2100 are considered). The definition of the indicator is a series of consecutive days where the used indicator is below -1. Read More
The existing climate refers to the entire historical period of the last 40 years (1979 - 2016) the methodology employed for the computation is exhaustively explained in the Background paper.
There are reference periods for the existing climate and for the future scenarios the average duration is computed over such periods in a statistical sense (for future years from 2060 to 2100 are considered). The definition of the indicator is a series of consecutive days where the used indicator is below -1. Read More
Drought hazard SMA 5-year return period - SSP5 Upper bound
Drought Hazard map based on the SMA-1 indicator (Standardised Moisture Anomaly cumulated on a 1-month window). The map refers to the return period RT = 5 Years and it is computated on the basis of exceeding the SMA-1 value of one Sigma in each pixel of the analyised domain for a duration of at least 3 consecutive months using SSP5 Upper bound Climate change scenario.
The existing climate refers to the entire historical period of the last 40 years (1979 - 2016) the methodology employed for the computation is exhaustively explained in the Background paper.
There are reference periods for the existing climate and for the future scenarios the average duration is computed over such periods in a statistical sense (for future years from 2060 to 2100 are considered). The definition of the indicator is a series of consecutive days where the used indicator is below -1. Read More
The existing climate refers to the entire historical period of the last 40 years (1979 - 2016) the methodology employed for the computation is exhaustively explained in the Background paper.
There are reference periods for the existing climate and for the future scenarios the average duration is computed over such periods in a statistical sense (for future years from 2060 to 2100 are considered). The definition of the indicator is a series of consecutive days where the used indicator is below -1. Read More
Drought hazard SPI-6 10-year return period - Existing climate
Drought Hazard map based on the SPI-6 indicator (Standardised Precipitation Index cumulated on a 6-month window). The map refers to the return period RT = 10 Years and it is computated on the basis of exceeding the SPI-6 value of one Sigma in each pixel of the analyised domain for a duration of at least 3 consecutive months.
The existing climate refers to the entire historical period of the last 40 years (1979 - 2016) the methodology employed for the computation is exhaustively explained in the Background paper.
There are reference periods for the existing climate and for the future scenarios the average duration is computed over such periods in a statistical sense (for future years from 2060 to 2100 are considered). The definition of the indicator is a series of consecutive days where the used indicator is below -1. Read More
The existing climate refers to the entire historical period of the last 40 years (1979 - 2016) the methodology employed for the computation is exhaustively explained in the Background paper.
There are reference periods for the existing climate and for the future scenarios the average duration is computed over such periods in a statistical sense (for future years from 2060 to 2100 are considered). The definition of the indicator is a series of consecutive days where the used indicator is below -1. Read More
Drought hazard SPI-6 10-year return period - SSP1 Lower bound
Drought Hazard map based on the SPI-6 indicator (Standardised Precipitation Index cumulated on a 6-month window). The map refers to the return period RT = 10 Years and it is computated on the basis of exceeding the SPI-6 value of one Sigma in each pixel of the analyised domain for a duration of at least 3 consecutive months using SSP1 Lower bound Climate change scenario.
The existing climate refers to the entire historical period of the last 40 years (1979 - 2016) the methodology employed for the computation is exhaustively explained in the Background paper.
There are reference periods for the existing climate and for the future scenarios the average duration is computed over such periods in a statistical sense (for future years from 2060 to 2100 are considered). The definition of the indicator is a series of consecutive days where the used indicator is below -1. Read More
The existing climate refers to the entire historical period of the last 40 years (1979 - 2016) the methodology employed for the computation is exhaustively explained in the Background paper.
There are reference periods for the existing climate and for the future scenarios the average duration is computed over such periods in a statistical sense (for future years from 2060 to 2100 are considered). The definition of the indicator is a series of consecutive days where the used indicator is below -1. Read More
Drought hazard SPI-6 10-year return period - SSP5 Upper bound
Drought Hazard map based on the SPI-6 indicator (Standardised Precipitation Index cumulated on a 6-month window). The map refers to the return period RT = 10 Years and it is computated on the basis of exceeding the SPI-6 value of one Sigma in each pixel of the analyised domain for a duration of at least 3 consecutive months using SSP5 Upper bound Climate change scenario.
The existing climate refers to the entire historical period of the last 40 years (1979 - 2016) the methodology employed for the computation is exhaustively explained in the Background paper.
There are reference periods for the existing climate and for the future scenarios the average duration is computed over such periods in a statistical sense (for future years from 2060 to 2100 are considered). The definition of the indicator is a series of consecutive days where the used indicator is below -1. Read More
The existing climate refers to the entire historical period of the last 40 years (1979 - 2016) the methodology employed for the computation is exhaustively explained in the Background paper.
There are reference periods for the existing climate and for the future scenarios the average duration is computed over such periods in a statistical sense (for future years from 2060 to 2100 are considered). The definition of the indicator is a series of consecutive days where the used indicator is below -1. Read More
Drought hazard SPI-6 25-year return period - Existing climate
Drought Hazard map based on the SPI-6 indicator (Standardised Precipitation Index cumulated on a 6-month window). The map refers to the return period RT = 25 Years and it is computated on the basis of exceeding the SPI-6 value of one Sigma in each pixel of the analyised domain for a duration of at least 3 consecutive months.
The existing climate refers to the entire historical period of the last 40 years (1979 - 2016) the methodology employed for the computation is exhaustively explained in the Background paper.
There are reference periods for the existing climate and for the future scenarios the average duration is computed over such periods in a statistical sense (for future years from 2060 to 2100 are considered). The definition of the indicator is a series of consecutive days where the used indicator is below -1. Read More
The existing climate refers to the entire historical period of the last 40 years (1979 - 2016) the methodology employed for the computation is exhaustively explained in the Background paper.
There are reference periods for the existing climate and for the future scenarios the average duration is computed over such periods in a statistical sense (for future years from 2060 to 2100 are considered). The definition of the indicator is a series of consecutive days where the used indicator is below -1. Read More
Drought hazard SPI-6 25-year return period - SSP1 Lower bound
Drought Hazard map based on the SPI-6 indicator (Standardised Precipitation Index cumulated on a 6-month window). The map refers to the return period RT = 25 Years and it is computated on the basis of exceeding the SPI-6 value of one Sigma in each pixel of the analyised domain for a duration of at least 3 consecutive months using SSP5 Upper bound Climate change scenario.
The existing climate refers to the entire historical period of the last 40 years (1979 - 2016) the methodology employed for the computation is exhaustively explained in the Background paper.
There are reference periods for the existing climate and for the future scenarios the average duration is computed over such periods in a statistical sense (for future years from 2060 to 2100 are considered). The definition of the indicator is a series of consecutive days where the used indicator is below -1. Read More
The existing climate refers to the entire historical period of the last 40 years (1979 - 2016) the methodology employed for the computation is exhaustively explained in the Background paper.
There are reference periods for the existing climate and for the future scenarios the average duration is computed over such periods in a statistical sense (for future years from 2060 to 2100 are considered). The definition of the indicator is a series of consecutive days where the used indicator is below -1. Read More
Drought hazard SPI-6 25-year return period - SSP5 Upper bound
Drought Hazard map based on the SPI-6 indicator. The map refers to the return period RT = 25 Years and it is computated on the basis of exceeding the SPI-6 value of one Sigma in each pixel of the analyised domain for a duration of at least 3 consecutive months using SSP5 Upper bound Climate change scenario.
The existing climate refers to the entire historical period of the last 40 years (1979 - 2016) the methodology employed for the computation is exhaustively explained in the Background paper.
There are reference periods for the existing climate and for the future scenarios the average duration is computed over such periods in a statistical sense (for future years from 2060 to 2100 are considered). The definition of the indicator is a series of consecutive days where the used indicator is below -1. Read More
The existing climate refers to the entire historical period of the last 40 years (1979 - 2016) the methodology employed for the computation is exhaustively explained in the Background paper.
There are reference periods for the existing climate and for the future scenarios the average duration is computed over such periods in a statistical sense (for future years from 2060 to 2100 are considered). The definition of the indicator is a series of consecutive days where the used indicator is below -1. Read More