parIni.MAX: Initial estimation of GPD parameters for an aggregated renewal model

Description

Initial estimation for an aggregated renewal model with GPD marks.

Usage

parIni.MAX(MAX, threshold, distname.y = "exp")
parIni.OTS(OTS, threshold, distname.y = "exp")

Arguments

MAX

A list describing partial observations of MAX type. These are block maxima or block $r$-largest statistics. The list must contain elements named block, effDuration, r, and data (

OTS

A list describing partial observations of OTS type. These are observations above the block thresholds, each being not smaller than threshold. This list contains block, effDuration, thre

threshold

The threshold of the POT-renewal model. This is the location parameter of the marks from which Largest Order Statistics are observed.

distname.y

The name of the distribution. For now this can be "exp" or "exponential" for exponential excesses implying Gumbel block maxima, or "gpd" for GPD excesses implying GEV block maxima. The initialisation is t

Value

A vector containing the estimate of the Poisson rate $\lambda$, and the estimates of the parameters for the target distribution of the excesses. For exponential excesses, these are simply a rate parameter. For GPD excesses, these are the scale and shape parameters, the second taken as zero.

Details

The functions estimate the Poisson rate lambda along with the shape parameter say sigma for exponential excesses. If the target distribution is GPD, then the initial shape parameter is taken to be 0. In the "MAX" case, the estimates are obtained by regressing the maxima or $r$-Largest Order Statistics within the blocks on the log-duration of the blocks. The response for a block is the minimum of the $r$ available Largest Order Statistics as found within the block, and $r$ will generally vary across block. When some blocks contain $r > 1$ largest order statistics, the corresponding spacings are used to compute a spacings-based estimation of $\sigma$. This estimator is independent of the regression estimator for $\sigma$ and the two estimators can be combined in a weighted mean. In the "OTS" case, the estimate of lambda is obtained by a Poisson regression using the log durations of the blocks as an offset. The estimate of sigma is simply the mean of all the available excesses, which by assumption share the same exponential distribution.

References

See the document Renext Computing Details.

Examples

Run this code

set.seed(1234)
## initialisation for 'MAX' data
u <- 10
nBlocks <- 30
nSim <- 100
ParMAX <- matrix(NA, nrow = nSim, ncol = 2)
colnames(ParMAX) <- c("lambda", "sigma")

for (i in 1:nSim) {
  rd <- rRendata(threshold = u,
                 effDuration = 1,
                 lambda = 12,
                 MAX.effDuration = c(60, rexp(nBlocks)),
                 MAX.r = c(5, 2 + rpois(nBlocks, lambda = 1)),
                 distname.y = "exp", par.y = c(rate = 1 / 100))

  MAX <- Renext:::makeMAXdata(rd)
  pari <- parIni.MAX(MAX = MAX, threshold = u)
  ParMAX[i, ] <- pari   
}
## the same for OTS data
u <- 10
nBlocks <- 10
nSim <- 100
ParOTS <- matrix(NA, nrow = nSim, ncol = 2)
colnames(ParOTS) <- c("lambda", "sigma")
rds <- list()

for (i in 1:nSim) {
  rd <- rRendata(threshold = u,
                 effDuration = 1,
                 lambda = 12,
                 OTS.effDuration = rexp(nBlocks, rate = 1 / 10),
                 OTS.threshold = u + rexp(nBlocks, rate = 1 / 10),
                 distname.y = "exp", par.y = c(rate = 1 / 100))
  rds[[i]] <- rd
  OTS <-  Renext:::makeOTSdata(rd)
  pari <- parIni.OTS(OTS = OTS, threshold = u)
  ParOTS[i, ] <- pari   
}

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