R: Precipitation Occurrence Multi-Site Model

PrecipitationOccurrenceMultiSiteModel {RGENERATEPREC}

R Documentation

Precipitation Occurrence Multi-Site Model

Description

This functions creates a stochastic Occurrence Multi-Site Model for the variable x (PrecipitationOccurrenceMultiSiteModel S3 object) through a calibration from observed data.

Usage

PrecipitationOccurrenceMultiSiteModel(
  x,
  exogen = NULL,
  station = names(x),
  origin = origin,
  valmin = 0.5,
  multisite_type = "wilks",
  tolerance_wilks = 0.001,
  p = 2,
  ...
)

Arguments

`x`	data frame (each column is a site) of variable utilized for the auto-regression of its occurrence, e.g. daily precipitaton
`exogen`	exogenous predictors
`station`	character string vectors containing the codes of the station used for model calibration
`origin`	character string (yyyy-dd-mm) indicating the date of the first row of `"x"`.
`valmin`	minimum admitted value for daily precipitation amount
`multisite_type`	string indicating the utilized approach for spatial multi-site dependence description. Default is `"wilks"`.
`tolerance_wilks`	see `tolerance` used by `omega_inv` through `CCGamma`
`p`	auto-regression order
`...`	further arguments

Value

The function returns a PrecipitationOccurrenceModel-class S3 object containing the following elements:

... PrecipitationOccurrenceModel S3 class objects for each analyzed site. The name is the site (or station) code

ccgama CCGammaObjectListPerEachMonth object, i.e. matices of Gaussian Inter-Site Correlation returned by CCGamma;

type string indicating the utilized approach for spatial multi-site dependence description, only "wilks" type is implemented;

station character string vectors containing the codes of the station used in PrecipitationMultiSiteOccurrenceModel.

Examples


library(RGENERATEPREC)

data(trentino)

year_min <- 1961
year_max <- 1990
origin <- paste(year_min,1,1,sep="-")

period <- PRECIPITATION$year>=year_min & PRECIPITATION$year<=year_max
period_temp <- TEMPERATURE_MAX$year>=year_min & TEMPERATURE_MAX$year<=year_max

prec_mes <- PRECIPITATION[period,]
Tx_mes <- TEMPERATURE_MAX[period_temp,]
Tn_mes <- TEMPERATURE_MIN[period_temp,]
accepted <- array(TRUE,length(names(prec_mes)))
names(accepted) <- names(prec_mes)
for (it in names(prec_mes)) {
	acc <- TRUE
	acc <- (length(which(!is.na(Tx_mes[,it])))==length(Tx_mes[,it]))
	acc <- (length(which(!is.na(Tn_mes[,it])))==length(Tn_mes[,it])) & acc
	accepted[it]  <- (length(which(!is.na(prec_mes[,it])))==length(prec_mes[,it])) & acc
	
}

valmin <- 1.0
prec_mes <- prec_mes[,accepted]



Tx_mes <- Tx_mes[,accepted]
Tn_mes <- Tn_mes[,accepted]
prec_occurrence_mes <- prec_mes>=valmin

station <- names(prec_mes)[!(names(prec_mes) %in% c("day","month","year"))]
station <- station[1:2] # to save example elapsed time!!
exogen <- Tx_mes-Tn_mes
months <- factor(prec_mes$month)

#' ### Not Run!! 
# The following lines are commented to save example elapsed time!!
model_multisite <- PrecipitationOccurrenceMultiSiteModel(x=prec_mes,exogen=exogen,
origin=origin,multisite_type="wilks")

### Not Run!! 
#  The following lines are commented to save example elapsed time!!
model_multisite_logit <- PrecipitationOccurrenceMultiSiteModel(x=prec_mes,exogen=exogen,
origin=origin,multisite_type="logit")