Apart from forecasts of Essential Climate Variables, Climate Services also provide a variety of the sectoral indicators that are often required for Climate Services people, including researchers, decision-makers, farmers, etc.
In the MEDGOLD project, 10 indicators which were identified as critical indices for the three agricultural sectors - grape/wine, olive/olive oil and wheat/pasta - have been considered in this CSIndicators package.
The computing functions and the corresponding indicators are listed as follows:
The above functions can take both multidimensional arrays and the s2dv_cube objects (see note below). Taking PeriodAccumulation as example, CST_PeriodAccumulation handles the latter and PeriodAccumulation without the prefix can compute multidimensional arrays.
Note: s2dv_cube and array classes can be handled by the functions in CSIndicators. See Section 2 in vignette Data retrieval and storage from CSTools package for more information.
There are some supplementary functions which must be called to smoothly run the above functions.
When the period selection is required, the start
and
end
parameters have to be provided to cut out the portion
in time_dim
. Otherwise, the function will take the
entire time_dim
.
The examples of computing the aforementioned indicators are given by functions as follows.
PeriodAccumulation
(and
CST_PeriodAccumulation
) computes the sum of a given
variable in a period.
Here, two indicators are used to show how this function works: Spring Total Precipitation (SprR) and Harvest Total Precipitation (HarvestR). Both indices represent the total precipitation but in different periods, 21st April - 21st June for SprR and 21st August - 21st October for HarvestR.
First, load the required libraries, CSIndicators, CSTools, etc by running
library(CSIndicators)
library(CSTools)
library(zeallot)
library(s2dv)
To obtain the precipitation forecast and observation, we load the
daily precipitation (prlr given in var
)
data sets of ECMWF SEAS5 seasonal forecast and ERA5 reanalysis for the
four starting dates 20130401-20160401 (provided in sdates
)
with the entire 7-month forecast time, April-October (214 days in total
given in parameter leadtimemax
).
The pathways of SEAS5 and ERA5 are given in the lists with some whitecards (inside two dollar signs) used to replace the variable name and iterative items such as year and month. See details of requirements in Section 5 in vignette Data retrieval and storage from CSTools package.
The spatial domain covers part of Douro Valley of Northern Portugal
lon=[352.25, 353], lat=[41, 41.75]. These four values are provided in
lonmin
, lonmax
, latmin
and
latmax
.
With grid
set to r1440x721, the SEAS5
forecast would be interpolated to the 0.25-degree ERA5 grid by using the
bicubic method given in method
.
sdates <- paste0(2013:2016, '04', '01')
lat_min = 41
lat_max = 41.75
lon_min = 352.25
lon_max = 353
S5path_prlr <- paste0("/esarchive/exp/ecmwf/system5c3s/daily_mean/$var$_s0-24h/$var$_$sdate$.nc")
prlr_exp <- CST_Start(dataset = S5path_prlr,
var = "prlr",
member = startR::indices(1:3),
sdate = sdates,
ftime = startR::indices(1:214),
lat = startR::values(list(lat_min, lat_max)),
lat_reorder = startR::Sort(decreasing = TRUE),
lon = startR::values(list(lon_min, lon_max)),
lon_reorder = startR::CircularSort(0, 360),
synonims = list(lon = c('lon', 'longitude'),
lat = c('lat', 'latitude'),
member = c('member', 'ensemble'),
ftime = c('ftime', 'time')),
transform = startR::CDORemapper,
transform_extra_cells = 2,
transform_params = list(grid = "r1440x721",
method = "bicubic"),
transform_vars = c('lat', 'lon'),
return_vars = list(lat = NULL,
lon = NULL, ftime = 'sdate'),
retrieve = TRUE)
dates_exp <- prlr_exp$attrs$Dates
path_ERA5prlr_CDS <- paste0("/esarchive/recon/ecmwf/era5/daily_mean/$var$_f1h-r1440x721cds/$var$_$date$.nc")
prlr_obs <- CST_Start(dataset = path_ERA5prlr_CDS,
var = "prlr",
date = unique(format(dates_exp, '%Y%m')),
ftime = startR::values(dates_exp),
ftime_across = 'date',
ftime_var = 'ftime',
merge_across_dims = TRUE,
split_multiselected_dims = TRUE,
lat = startR::values(list(lat_min, lat_max)),
lat_reorder = startR::Sort(decreasing = TRUE),
lon = startR::values(list(lon_min, lon_max)),
lon_reorder = startR::CircularSort(0, 360),
synonims = list(lon = c('lon', 'longitude'),
lat = c('lat', 'latitude'),
ftime = c('ftime', 'time')),
transform = startR::CDORemapper,
transform_extra_cells = 2,
transform_params = list(grid = "r1440x721",
method = "bicubic"),
transform_vars = c('lat', 'lon'),
return_vars = list(lon = NULL,
lat = NULL,
ftime = 'date'),
retrieve = TRUE)
The output contains data and metadata for the experiment and the
observations. The elements prlr_exp$data
and
prlr_obs$data
have dimensions:
dim(prlr_exp$data)
# dataset var member sdate ftime lat lon
# 1 1 3 4 214 4 4
dim(prlr_obs$data)
# dataset var sdate ftime lat lon
# 1 1 4 214 4 4
To compute SprR of forecast and observation, we can run:
SprR_exp <- CST_PeriodAccumulation(prlr_exp, start = list(21, 4), end = list(21, 6))
SprR_obs <- CST_PeriodAccumulation(prlr_obs, start = list(21, 4), end = list(21, 6))
The start
and end
are the initial and final
dates and the day must be given before the month as above. They will be
applied along the dimension time_dim
(it is set to ‘ftime’
by default).
As mentioned, these parameters are optional, the function will take
the entire timeseries when the period is not specified in
start
and end
.
The dimensions of SprR forecasts and observations are:
dim(SprR_exp$data)
# dataset var member sdate lat lon
# 1 1 3 4 4 4
dim(SprR_obs$data)
# dataset var sdate lat lon
# 1 1 4 4 4
The forecast SprR for the 1st member from 2013-2016 of the 1st grid point in mm are:
Dry springs will delay vegetative growth and reduce vigour and leaf area total surface. Fungal disease pressure will be lower and therefore there will be less need for protective and / or curative treatments, translating as less costs. Wet springs will promote higher vigour, increase the risk of fungal disease and disrupt vineyard operations as it may prevent machinery from getting in the vineyard due to mud. They are usually associated with higher costs.
On the other hand, another moisture-related indicators,
HarvestR, can be computed by using
PeriodAccumulation
as well, with the defined period as the
following lines.
HarvestR_exp <- CST_PeriodAccumulation(prlr_exp, start = list(21, 8), end = list(21, 10))
HarvestR_obs <- CST_PeriodAccumulation(prlr_obs, start = list(21, 8), end = list(21, 10))
The forecast HarvestR for the 1st member from 2013-2016 of the 1st grid point in mm are:
To compute the 2013-2016 ensemble-mean bias of forecast HarvestR, run
fcst <- drop(HarvestR_exp$data) * 86400 * 1000
obs <- drop(HarvestR_obs$data) * 86400 * 1000
Bias <- MeanDims((fcst - InsertDim(obs, 1, dim(fcst)['member'])), 'member')
To plot the map of ensemble-mean bias of HarvestR forecast, run
cols <- c('#b2182b', '#d6604d', '#f4a582', '#fddbc7', '#d1e5f0',
'#92c5de', '#4393c3', '#2166ac')
PlotEquiMap(Bias[1, , ], lon = prlr_obs$coords$lon, lat = prlr_obs$coords$lat,
intylat = 1, intxlon = 1, width = 6, height = 6,
filled.continents = FALSE, units = 'mm', title_scale = .8,
axes_label_scale = 1, axes_tick_scale = 1, col_inf = cols[1],
margin_scale = c(1, 1, 1, 1), cols = cols[2:7], col_sup = cols[8],
brks = seq(-60, 60, 20), colNA = 'white',
toptitle = 'Ensemble-mean bias of HarvestR in 2013',
bar_label_scale = 1.5, bar_extra_margin = c(0, 0, 0, 0), units_scale = 2)
You will see the following maps of HarvestR bias in 2013.
In 2013, the ensemble-mean SEAS5 seasonal forecast of HarvestR is underestimated by up to 60 mm over Douro Valley region (the central four grid points).
For the function PeriodMean
, we use Growing Season
Temperature (GST) as an example. GST is defined as the
average of daily average temperatures between April 1st to October 31st
in the Northern Hemisphere. It provides information onto which are the
best suited varieties for a given site or, inversely, which are the best
places to grow a specific variety. For existing vineyards, GST also
informs on the suitability of its varieties for the climate of specific
years, explaining quality and production variation. Many grapevine
varieties across the world have been characterized in function of their
GST optimum.
Firstly, we prepare a sample data of daily mean temperature of SEAS5 and ERA5 data sets with the same starting dates, spatial domain, interpolation grid and method by running
S5path <- paste0("/esarchive/exp/ecmwf/system5c3s/daily_mean/$var$_f6h/$var$_$sdate$.nc")
tas_exp <- CST_Start(dataset = S5path,
var = "tas",
member = startR::indices(1:3),
sdate = sdates,
ftime = startR::indices(1:214),
lat = startR::values(list(lat_min, lat_max)),
lat_reorder = startR::Sort(decreasing = TRUE),
lon = startR::values(list(lon_min, lon_max)),
lon_reorder = startR::CircularSort(0, 360),
synonims = list(lon = c('lon', 'longitude'),
lat = c('lat', 'latitude'),
member = c('member', 'ensemble'),
ftime = c('ftime', 'time')),
transform = startR::CDORemapper,
transform_extra_cells = 2,
transform_params = list(grid = "r1440x721",
method = "bicubic"),
transform_vars = c('lat', 'lon'),
return_vars = list(lat = NULL,
lon = NULL, ftime = 'sdate'),
retrieve = TRUE)
dates_exp <- tas_exp$attrs$Dates
ERA5path <- paste0("/esarchive/recon/ecmwf/era5/daily_mean/$var$_f1h-r1440x721cds/$var$_$date$.nc")
tas_obs <- CST_Start(dataset = ERA5path,
var = "tas",
date = unique(format(dates_exp, '%Y%m')),
ftime = startR::values(dates_exp),
ftime_across = 'date',
ftime_var = 'ftime',
merge_across_dims = TRUE,
split_multiselected_dims = TRUE,
lat = startR::values(list(lat_min, lat_max)),
lat_reorder = startR::Sort(decreasing = TRUE),
lon = startR::values(list(lon_min, lon_max)),
lon_reorder = startR::CircularSort(0, 360),
synonims = list(lon = c('lon', 'longitude'),
lat = c('lat', 'latitude'),
ftime = c('ftime', 'time')),
transform = startR::CDORemapper,
transform_extra_cells = 2,
transform_params = list(grid = "r1440x721",
method = "bicubic"),
transform_vars = c('lat', 'lon'),
return_vars = list(lon = NULL,
lat = NULL,
ftime = 'date'),
retrieve = TRUE)
The output contains observations tas_obs$data
and
forecast tas_exp$data
, and their dimensions and summaries
are like
dim(tas_obs$data)
# dataset var sdate ftime lat lon
# 1 1 4 214 4 4
dim(tas_exp$data)
# dataset var member sdate ftime lat lon
# 1 1 3 4 214 4 4
summary(tas_obs$data - 273.15)
# Min. 1st Qu. Median Mean 3rd Qu. Max.
# 3.627 13.974 17.248 17.294 20.752 30.206
summary(tas_exp$data - 273.15)
# Min. 1st Qu. Median Mean 3rd Qu. Max.
# 0.5363 11.6517 16.5610 16.4961 21.2531 31.4063
To compute the GST for both observation and forecast, run the following lines
# change the unit of temperature from °C to K
tas_exp$data <- tas_exp$data - 273.15
tas_obs$data <- tas_obs$data - 273.15
# compute GST
GST_exp <- CST_PeriodMean(tas_exp, start = list(1, 4), end = list(31, 10))
GST_obs <- CST_PeriodMean(tas_obs, start = list(1, 4), end = list(31, 10))
Since the period considered for GST is the entire period for starting
month of April, in this case the start
and end
parameters could be ignored.
The summaries and dimensions of the output are as follows:
summary(GST_exp$data)
# Min. 1st Qu. Median Mean 3rd Qu. Max.
# 14.23 15.78 16.50 16.50 17.17 18.70
summary(GST_obs$data)
# Min. 1st Qu. Median Mean 3rd Qu. Max.
# 15.34 16.77 17.22 17.29 18.00 18.75
dim(GST_exp$data)
# dataset var member sdate lat lon
# 1 1 3 4 4 4
dim(GST_obs$data)
# dataset var sdate lat lon
# 1 1 4 4 4
Here, we plot the 2013-2016 mean climatology of ERA5 GST by running
# compute ERA5 GST climatology
GST_Clim <- MeanDims(drop(GST_obs$data), 'sdate')
cols <- c('#ffffd4','#fee391','#fec44f','#fe9929','#ec7014','#cc4c02','#8c2d04')
PlotEquiMap(GST_Clim, lon = tas_obs$coords$lon, lat = tas_obs$coords$lat,
intylat = 1, intxlon = 1, width = 6, height = 6,
filled.continents = FALSE, units = '°C', title_scale = .8,
axes_label_scale = 1, axes_tick_scale = 1, col_inf = cols[1],
margin_scale = c(1, 1, 1, 1), cols = cols[2:6], col_sup = cols[7],
brks = seq(16, 18.5, 0.5), colNA = 'white', bar_label_scale = 1.5,
toptitle = '2013-2016 mean ERA5 GST',
bar_extra_margin = c(0, 0, 0, 0), units_scale = 2)
The ERA5 GST climatology is shown as below.
ERA5 GST ranges from 17-18.5°C over the Douro Valley region for the period from 2013-2016 as shown in the figure.
For the function TotalTimeExceedingThreshold
,
SU35 (Number of Heat Stress Days - 35°C) is taken as an
example here. 35°C is the average established threshold for
photosynthesis to occur in the grapevine. Above this temperature, the
plant closes its stomata. If this situation occurs after veraison,
maturation will be arrested for as long as the situation holds,
decreasing sugar, polyphenol and aroma precursor levels, all essential
for grape and wine quality. The higher the index, the lower will be the
berry quality and aptitude to produce quality grapes.
SU35 is defined as the Total count of days when daily maximum temperatures exceed 35°C in the seven months into the future. There are three indicators sharing the similar definition as SU35: SU36, SU40 and Spr32. Their definition are listed as follows.
These indicators can be computed as well by using the function
TotalTimeExceedingThreshold
with different thresholds and
periods indicated.
Here, we take SU35 as example, therefore the daily temperature maximum of the entire 7-month forecast period is needed for the computation of this indicator.
Load SEAS5 and ERA5 daily temperature maximum by running
S5path <- paste0("/esarchive/exp/ecmwf/system5c3s/daily/$var$/$var$_$sdate$.nc")
tasmax_exp <- CST_Start(dataset = S5path,
var = "tasmax",
member = startR::indices(1:3),
sdate = sdates,
ftime = startR::indices(1:214),
lat = startR::values(list(lat_min, lat_max)),
lat_reorder = startR::Sort(decreasing = TRUE),
lon = startR::values(list(lon_min, lon_max)),
lon_reorder = startR::CircularSort(0, 360),
synonims = list(lon = c('lon', 'longitude'),
lat = c('lat', 'latitude'),
member = c('member', 'ensemble'),
ftime = c('ftime', 'time')),
transform = startR::CDORemapper,
transform_extra_cells = 2,
transform_params = list(grid = "r1440x721",
method = "bicubic"),
transform_vars = c('lat', 'lon'),
return_vars = list(lat = NULL,
lon = NULL, ftime = 'sdate'),
retrieve = TRUE)
dates_exp <- tasmax_exp$attrs$Dates
ERA5path <- paste0("/esarchive/recon/ecmwf/era5/daily/$var$-r1440x721cds/$var$_$date$.nc")
tasmax_obs <- CST_Start(dataset = ERA5path,
var = "tasmax",
date = unique(format(dates_exp, '%Y%m')),
ftime = startR::values(dates_exp),
ftime_across = 'date',
ftime_var = 'ftime',
merge_across_dims = TRUE,
split_multiselected_dims = TRUE,
lat = startR::values(list(lat_min, lat_max)),
lat_reorder = startR::Sort(decreasing = TRUE),
lon = startR::values(list(lon_min, lon_max)),
lon_reorder = startR::CircularSort(0, 360),
synonims = list(lon = c('lon', 'longitude'),
lat = c('lat', 'latitude'),
ftime = c('ftime', 'time')),
transform = startR::CDORemapper,
transform_extra_cells = 2,
transform_params = list(grid = "r1440x721",
method = "bicubic"),
transform_vars = c('lat', 'lon'),
return_vars = list(lon = NULL,
lat = NULL,
ftime = 'date'),
retrieve = TRUE)
Check the unit of temperature to from °C to K for the comparison with the threshold defined (for example 35°C here).
Computing SU35 for forecast and observation by running
threshold <- 35
SU35_exp <- CST_TotalTimeExceedingThreshold(tasmax_exp, threshold = threshold,
start = list(1, 4), end = list(31, 10))
SU35_obs <- CST_TotalTimeExceedingThreshold(tasmax_obs, threshold = threshold,
start = list(1, 4), end = list(31, 10))
The summaries of SU35 forecasts and observations are given below.
summary(SU35_exp$data)
# Min. 1st Qu. Median Mean 3rd Qu. Max.
# 0.000 2.000 5.000 7.135 12.000 26.000
summary(SU35_obs$data)
# Min. 1st Qu. Median Mean 3rd Qu. Max.
# 0.000 0.000 1.000 2.609 5.000 10.000
As shown in the summaries, SEAS5 SU35 forecasts are overestimated by 5 days in terms of mean value.
Therefore, CST_BiasCorrection
is used to bias adjust the
SU35 forecasts.
res <- CST_BiasCorrection(obs = SU35_obs, exp = SU35_exp)
SU35_exp_BC <- drop(res$data)
summary(SU35_exp_BC)
# Min. 1st Qu. Median Mean 3rd Qu. Max.
# -1.523 0.000 1.613 2.830 4.756 17.768
Since there are negative values after bias adjustment, all negative data is converted to zero.
SU35_exp_BC[SU35_exp_BC < 0] <- 0
summary(SU35_exp_BC)
# Min. 1st Qu. Median Mean 3rd Qu. Max.
# 0.000 0.000 1.613 2.941 4.756 17.768
Plot the bias-adjusted SU35 forecast in 2016 by running
SU35_obs_Y2016 <- drop(SU35_obs$data)[4, , ]
SU35_exp_Y2016 <- MeanDims(drop(SU35_exp$data)[, 4, , ], 'member')
SU35_exp_BC_Y2016 <- MeanDims(SU35_exp_BC[, 4, , ], 'member')
cols <- c("#fee5d9", "#fcae91", "#fb6a4a", "#de2d26","#a50f15")
toptitle <- 'ERA5 SU35 forecast in 2016'
PlotEquiMap(SU35_obs_Y2016,
lon = tasmax_obs$coords$lon, lat = tasmax_obs$coords$lat,
intylat = 1, intxlon = 1, width = 6, height = 6,
filled.continents = FALSE, units = 'day', title_scale = .8,
axes_label_scale = 1, axes_tick_scale = 1, margin_scale = c(1, 1, 1, 1),
cols = cols[1:4], col_sup = cols[5], brks = seq(0, 8, 2),
toptitle = toptitle,
colNA = cols[1], bar_label_scale = 1.5,
bar_extra_margin = c(0, 0, 0, 0), units_scale = 2)
toptitle <- 'SU35 forecast in 2016'
PlotEquiMap(SU35_exp_Y2016,
lon = tasmax_obs$coords$lon, lat = tasmax_obs$coords$lat,
intylat = 1, intxlon = 1, width = 6, height = 6,
filled.continents = FALSE, units = 'day', title_scale = .8,
axes_label_scale = 1, axes_tick_scale = 1, margin_scale = c(1, 1, 1, 1),
cols = cols[1:4], col_sup = cols[5], brks = seq(0, 8, 2),
toptitle = toptitle,
colNA = cols[1], bar_label_scale = 1.5,
bar_extra_margin = c(0, 0, 0, 0), units_scale = 2)
toptitle <- 'Bias-adjusted SU35 forecast in 2016'
PlotEquiMap(SU35_exp_BC_Y2016,
lon = tasmax_obs$coords$lon, lat = tasmax_obs$coords$lat,
intylat = 1, intxlon = 1, width = 6, height = 6,
filled.continents = FALSE, units = 'day', title_scale = .8,
axes_label_scale = 1, axes_tick_scale = 1, margin_scale = c(1, 1, 1, 1),
cols = cols[1:4], col_sup = cols[5], brks = seq(0, 8, 2),
toptitle = toptitle,
colNA = cols[1], bar_label_scale = 1.5,
bar_extra_margin = c(0, 0, 0, 0), units_scale = 2)
You can see the figure as below.
As seen above, the bias-adjusted SU35 forecasts are much closer to the ERA5 results, although differences remain.
Beside of the original definition of SU35, here two supplementary
functions in the package CSIndicators
are demonstrated by
computing its another definition with the percentile adjustment.
The above two supplementary functions are required to compute SU35
with the percentile adjustment. The function AbsToProbs
would be applied to forecast and the QThreshold
would be
used to convert the observations to its percentile based on the given
threshold.
The revised definition of SU35 is to reduce the potential influence induced by the fixed threshold of temperature defined for the index, instead of using the absolute value, the percentile corresponding to 35°C for observation is compared to the percentile corresponding to the predicted daily maximum temperature before being considered as a ‘heat stress’ day.
As mentioned, the forecast is translated to its percentile by using
the function ABsToProbs
by running
exp_percentile <- AbsToProbs(tasmax_exp$data)
S5txP <- aperm(drop(exp_percentile), c(2, 1, 3, 4, 5))
After that, based on 35 of threshold, the percentile corresponding to each observational value can be calculated as follows.
obs_percentile <- QThreshold(tasmax_obs$data, threshold = 35)
obs_percentile <- drop(obs_percentile)
After translating both forecasts and observations into probabilities, the comparison can then be done by running
SU35_exp_Percentile <- TotalTimeExceedingThreshold(S5txP, threshold = obs_percentile,
time_dim = 'ftime')
Compute the same ensemble-mean SU35 with percentile adjustment in 2016 by running
Plot the same map for comparison
toptitle <- 'SU35 forecast with percentile adjustment in 2016'
PlotEquiMap(SU35_exp_per_Y2016,
lon = tasmax_obs$coords$lon, lat = tasmax_obs$coords$lat,
intylat = 1, intxlon = 1, width = 6, height = 6,
filled.continents = FALSE, units = 'day', title_scale = .8,
axes_label_scale = 1, axes_tick_scale = 1, margin_scale = c(1, 1, 1, 1),
cols = cols[1:4], col_sup = cols[5], brks = seq(0, 8, 2),
toptitle = toptitle,
colNA = cols[1], bar_label_scale = 1.5,
bar_extra_margin = c(0, 0, 0, 0), units_scale = 2)
As seen in the figure above, applying the percentile adjustment seems to implicitly adjust certain extent of bias which was observed in the non-bias-adjusted SEAS5 forecast.
The performance of comparison of skills between two definitions requires further analysis such as the application of more skill metrics.
The function ´AccumulationExceedingThreshold´ can compute GDD (Growing Degree Days).
The definition of GDD is the summation of daily differences between
daily average temperatures and 10°C between April 1st and October 31st.
Here, the tas (daily average temperature) used above (in Section 2.
PeriodMean) is loaded again (Please re-use the section of loading tas in
Section 2). As per the definition, threshold
is set to 10
with diff
set to TRUE so that the function will compute the
differences between daily temperature and the threshold given before
calculating summation.
Note: The data is in degrees Celsiusi at this point
GDD_exp <- CST_AccumulationExceedingThreshold(tas_exp, threshold = 10, diff = TRUE)
GDD_obs <- CST_AccumulationExceedingThreshold(tas_obs, threshold = 10, diff = TRUE)
The summaries of GDD are
summary(GDD_exp$data)
# Min. 1st Qu. Median Mean 3rd Qu. Max.
# 1021 1331 1480 1469 1596 1873
summary(GDD_obs$data)
# Min. 1st Qu. Median Mean 3rd Qu. Max.
# 1195 1483 1569 1583 1730 1874
To compute the correlation coefficient for the period from 2013-2016, run the following lines
# reorder the dimension
fcst <- Reorder(drop(GDD_exp$data), c(4, 3, 2, 1))
obs <- Reorder(drop(GDD_obs$data), c(3, 2, 1))
EnsCorr <- veriApply('EnsCorr', fcst = fcst, obs = obs, ensdim = 4, tdim = 3)
GDD_Corr <- Reorder(EnsCorr, c(2, 1))
To plot the map of correlation coefficient of GDD for the 2013-2016 period.
cols <- c("#f7fcf5", "#e5f5e0", "#c7e9c0", "#a1d99b", "#74c476")
toptitle <- '2013-2016 correlation coefficient of GDD'
PlotEquiMap(GDD_Corr, lon = tas_obs$coords$lon, lat = tas_obs$coords$lat,
intylat = 1, intxlon = 1, width = 6, height = 6,
filled.continents = FALSE, units = 'correlation',
title_scale = .8, axes_label_scale = 1, axes_tick_scale = 1,
margin_scale = c(1, 1, 1, 1), cols = cols, brks = seq(0.5, 1, 0.1),
toptitle = toptitle, bar_label_scale = 1.5,
bar_extra_margin = c(0, 0, 0, 0), units_scale = 2)
The map of correlation coefficient for the 2013-2016 period is shown as below.
The 2013-2016 correlation coefficients of the SEAS5 forecasts of GDD in reference with ERA5 reanalysis over Douro Valley range between 0.6 and 0.8.
One of the critical agricultural indicators related to dry spell is the Warm Spell Duration Index (WSDI), which is defined as the total count of days with at least 6 consecutive days when the daily maximum temperature exceeds its 90th percentile in the seven months into the future.
The maximum temperature data used in Section 3. Since the daily
maximum temperature needs to compare to its 90th percentile, the
function Threshold
in the CSIndicators
package
is required to compute the percentile of observations used for each day.
Here the same period (2013-2016) is considered.
The output will be the 90th percentile of each day of each grid point derived by using all the years in the data.See the dimension and summary as below.
dim(tx_p$data)
# dataset var ftime lat lon
# 1 1 214 4 4
summary(tx_p$data)
# Min. 1st Qu. Median Mean 3rd Qu. Max.
# 13.83 22.08 26.08 26.22 30.72 36.72
With the prepared threshold (90th percentile), the WSDI can be computed by running
WSDI_exp <- CST_TotalSpellTimeExceedingThreshold(tasmax_exp, threshold = tx_p, spell = 6)
WSDI_obs <- CST_TotalSpellTimeExceedingThreshold(tasmax_obs, threshold = tx_p, spell = 6)
After checking the summaries, compute the Fair Ranked Probability Skill Score (FRPSS) of WSDI by running the following lines
# Reorder the data
fcst <- Reorder(drop(WSDI_exp$data), c(4, 3, 2, 1))
obs <- Reorder(drop(WSDI_obs$data), c(3, 2, 1))
# summaries of WSDI
summary(fcst)
# Min. 1st Qu. Median Mean 3rd Qu. Max.
# 0.00 13.00 28.00 31.22 46.00 82.00
summary(obs)
# Min. 1st Qu. Median Mean 3rd Qu. Max.
# 9.00 19.00 22.50 23.25 26.00 33.00
# compute FRPSS
f <- veriApply('FairRpss', fcst = fcst, obs = obs, ensdim = 4, tdim = 3, prob = 1:2/3)$skillscore
WSDI_FRPSS <- Reorder(f, c(2,1))
Plot the map of WSDI FRPSS for the period from 2013-2016
cols <- c("#edf8fb", "#ccece6", "#99d8c9", "#66c2a4")
toptitle <- 'SEAS5 WSDI FRPSS (2013-2016)'
PlotEquiMap(WSDI_FRPSS, lon = tasmax_obs$coords$lon, lat = tasmax_obs$coords$lat,
intylat = 1, intxlon = 1, width = 6, height = 6,
filled.continents = FALSE, units = 'FRPSS', title_scale = .8,
axes_label_scale = 1, axes_tick_scale = 1, margin_scale = c(1, 1, 1, 1),
cols = cols[1:3], col_inf = 'white', col_sup = cols[4],
brks = seq(0, 0.9, 0.3), toptitle = toptitle, bar_label_scale = 1.5,
bar_extra_margin = c(0, 0, 0, 0), units_scale = 2)
The FRPSS map for 2013-2016 SEAS WSDI is shown as below.
As seen in the map, the FRPSS in the eastern part of Douro Valley falls in 0.6-0.9, which are good enough to be useful when compared to observational climatology.
In addition to the grape/wine sector focused here, the MEDGOLD project also works on the other two sectors: olive/olive oil and durum wheat/pasta. Furthermore, the climate services are also provided at the longer term (up to 30 years) by other project partners.
Click on MEDGOLD for more information.