lgammagpdcon(x, gshape = 1, gscale = 1,
u = qgamma(0.9, gshape, 1/gscale), xi = 0, phiu = TRUE,
log = TRUE)
nlgammagpdcon(pvector, x, phiu = TRUE, finitelik = FALSE)gshape, gscale, u,
sigmau, xi) or NULLlgammagpdcon gives
(log-)likelihood and
nlgammagpdcon gives the
negative log-likelihood.fgammagpdcon.
They are designed to be used for MLE in
fgammagpdcon but are
available for wider usage, e.g. constructing your own
extreme value mixture models.
Negative data are ignored.
See fgammagpdcon and
fgpd for full details.
Log-likelihood calculations are carried out in
lgammagpdcon, which
takes parameters as inputs in the same form as
distribution functions. The negative log-likelihood is a
wrapper for
lgammagpdcon, designed
towards making it useable for optimisation (e.g.
parameters are given a vector as first input). The tail
fraction phiu is treated separately to the other
parameters, to allow for all it's representations.
Unlike the distribution functions
gammagpdcon the
phiu must be either logical (TRUE or
FALSE) or numerical in range $(0, 1)$. The
default is to specify phiu=TRUE so that the tail
fraction is specified by gamma distribution $\phi_u =
1 - H(u)$, or phiu=FALSE to treat the tail
fraction as an extra parameter estimated using the sample
proportion. Specify a numeric phiu as
pre-specified probability $(0, 1)$. Notice that the
tail fraction probability cannot be 0 or 1 otherwise
there would be no contribution from either tail or bulk
components respectively.
The function
lgammagpdcon carries
out the calculations for the log-likelihood directly,
which can be exponentiated to give actual likelihood
using (log=FALSE).lgammagpd,
lgpd and
gpd
Other gammagpdcon: dgammagpdcon,
fgammagpdcon, gammagpdcon,
pgammagpdcon, qgammagpdcon,
rgammagpdcon