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% Generated by roxygen2: do not edit by hand
% Please edit documentation in R/TPI.R
\name{TPI}
\alias{TPI}
\title{Compute the Tripole Index (TPI) for the Interdecadal Pacific Oscillation (IPO)}
\usage{
TPI(data, data_lats, data_lons, index, type, lat_dim = "lat",
lon_dim = "lon", mask = NULL, monini = 11, fmonth_dim = "fmonth",
sdate_dim = "sdate", indices_for_clim = NULL, year_dim = "year",
month_dim = "month", member_dim = "member")
}
\arguments{
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\item{data}{A numerical array to be used for the index computation with the
dimensions: 1) latitude, longitude, start date, forecast month, and member
(in case of decadal predictions), 2) latitude, longitude, year, month and
member (in case of historical simulations), or 3) latitude, longitude, year
and month (in case of observations or reanalyses). This data has to be
provided, at least, over the whole region needed to compute the index.}
\item{data_lats}{A numeric vector indicating the latitudes of the data.}
\item{data_lons}{A numeric vector indicating the longitudes of the data.}
\item{lat_dim}{A character string of the name of the latitude dimension. The
default value is 'lat'.}
\item{lon_dim}{A character string of the name of the longitude dimension. The
default value is 'lon'.}
\item{mask}{An array of a mask (with 0's in the grid points that have to be
masked) or NULL (i.e., no mask is used). This parameter allows to remove
the values over land in case the dataset is a combination of surface air
temperature over land and sea surface temperature over the ocean. Also, it
can be used to mask those grid points that are missing in the observational
dataset for a fair comparison between the forecast system and the reference
dataset. The default value is NULL.}
\item{monini}{An integer indicating the month in which the forecast system is
initialized. Only used when parameter 'type' is 'dcpp'. The default value
is 11, i.e., initialized in November.}
\item{fmonth_dim}{A character string indicating the name of the forecast
month dimension. Only used if parameter 'type' is 'dcpp'. The default value
is 'fmonth'.}
\item{sdate_dim}{A character string indicating the name of the start date
dimension. Only used if parameter 'type' is 'dcpp'. The default value is
'sdate'.}
\item{indices_for_clim}{A numeric vector of the indices of the years to
compute the climatology for calculating the anomalies, or NULL so the
climatology is calculated over the whole period. If the data are already
anomalies, set it to FALSE. The default value is NULL.\cr
In case of parameter 'type' is 'dcpp', 'indices_for_clim' must be relative
to the first forecast year, and the climatology is automatically computed
over the actual common period for the different forecast years.}
\item{year_dim}{A character string indicating the name of the year dimension
The default value is 'year'. Only used if parameter 'type' is 'hist' or
'obs'.}
\item{month_dim}{A character string indicating the name of the month
dimension. The default value is 'month'. Only used if parameter 'type' is
'hist' or 'obs'.}
\item{member_dim}{A character string indicating the name of the member
dimension. The default value is 'member'. Only used if parameter 'type' is
'dcpp' or 'hist'.}
\item{A}{character string indicating the type of data ('dcpp' for
decadal predictions, 'hist' for historical simulations, or 'obs' for
observations or reanalyses).}
A numerical array of the TPI index with the dimensions of:
1) sdate, forecast year, and member (in case of decadal predictions);
2) year and member (in case of historical simulations); or
3) year (in case of observations or reanalyses).
The Tripole Index (TPI) for the Interdecadal Pacific Oscillation (IPO) is
computed as the difference of weighted-averaged SST anomalies over 10ºS-10ºN,
170ºE-270ºE minus the mean of the weighted-averaged SST anomalies over
25ºN-45ºN, 140ºE-215ºE and 50ºS-15ºS, 150ºE-200ºE (Henley et al., 2015).
}
\examples{
## Observations or reanalyses
obs = array(1:100, dim = c(year = 5, lat = 19, lon = 37, month = 12))
lat = seq(-90, 90, 10)
lon = seq(0, 360, 10)
index_obs = TPI(data = obs, data_lats = lat, data_lons = lon, type = 'obs')
## Historical simulations
hist = array(1:100, dim = c(year = 5, lat = 19, lon = 37, month = 12, member = 5))
lat = seq(-90, 90, 10)
lon = seq(0, 360, 10)
index_hist = TPI(data = hist, data_lats = lat, data_lons = lon, type = 'hist')
## Decadal predictions
dcpp = array(1:100, dim = c(sdate = 5, lat = 19, lon = 37, fmonth = 24, member = 5))
lat = seq(-90, 90, 10)
lon = seq(0, 360, 10)
index_dcpp = TPI(data = dcpp, data_lats = lat, data_lons = lon, type = 'dcpp', monini = 1)
}