distrMod (version 2.9.1)

Estimate-class: Estimate-class.

Description

Class of estimates.

Arguments

Objects from the Class

Objects can be created by calls of the form new("Estimate", ...). More frequently they are created via the generating function Estimator.

Slots

name

Object of class "character": name of the estimator.

estimate

Object of class "ANY": estimate.

estimate.call

Object of class "call": call by which estimate was produced.

Infos

object of class "matrix" with two columns named method and message: additional informations.

asvar

object of class "OptionalNumericOrMatrix" which may contain the asymptotic (co)variance of the estimator.

samplesize

object of class "numeric" --- the samplesize (only complete cases are counted) at which the estimate was evaluated.

completecases

object of class "logical" --- complete cases at which the estimate was evaluated.

nuis.idx

object of class "OptionalNumeric": indices of estimate belonging to the nuisance part.

fixed

object of class "OptionalNumeric": the fixed and known part of the parameter.

trafo

object of class "list": a list with components fct and mat (see below).

untransformed.estimate

Object of class "ANY": untransformed estimate.

untransformed.asvar

object of class "OptionalNumericOrMatrix" which may contain the asymptotic (co)variance of the untransformed estimator.

Methods

name

signature(object = "Estimate"): accessor function for slot name.

name<-

signature(object = "Estimate"): replacement function for slot name.

estimate

signature(object = "Estimate"): accessor function for slot estimate.

untransformed.estimate

signature(object = "Estimate"): accessor function for slot untransformed.estimate.

estimate.call

signature(object = "Estimate"): accessor function for slot estimate.call.

samplesize

signature(object = "Estimate"): (with additional argument onlycompletecases defaulting to TRUE returns the sample size; in case there are any incomplete cases and argument onlycompletecases is FALSE, the number of these is added to slot samplesize.

completecases

signature(object = "Estimate"): accessor function for slot completecases.

asvar

signature(object = "Estimate"): accessor function for slot asvar.

asvar<-

signature(object = "Estimate"): replacement function for slot asvar.

untransformed.asvar

signature(object = "Estimate"): accessor function for slot untransformed.asvar.

nuisance

signature(object = "Estimate"): accessor function for nuisance part of slot estimate.

main

signature(object = "Estimate"): accessor function for main part of slot estimate.

fixed

signature(object = "Estimate"): accessor function for slot fixed.

Infos

signature(object = "Estimate"): accessor function for slot Infos.

Infos<-

signature(object = "Estimate"): replacement function for slot Infos.

addInfo<-

signature(object = "Estimate"): function to add an information to slot Infos.

show

signature(object = "Estimate")

print

signature(object = "Estimate"): just as show, but with additional arguments digits.

Details for methods 'show', 'print'

Detailedness of output by methods show, print is controlled by the global option show.details to be set by distrModoptions.

As method show is used when inspecting an object by typing the object's name into the console, show comes without extra arguments and hence detailedness must be controlled by global options.

Method print may be called with a (partially matched) argument show.details, and then the global option is temporarily set to this value.

More specifically, when show.detail is matched to "minimal" you will be shown only the name/type of the estimator, the value of its main part, and, if present, the corresponding standard errors, as well as, also if present, the value of the nuisance part. When show.detail is matched to "medium", you will in addition see the class of the estimator, its call and its sample-size and, if present, the fixed part of the parameter and the asymptotic covariance matrix. Also the information gathered in the Infos slot is shown. Finally, when show.detail is matched to "maximal", and if, in addition, you estimate non-trivial (i.e. not the identity) transformation of the parameter of the parametric family, you will also be shown this transformation in form of its function and its derivative matrix at the estimated parameter value, as well as the estimator (with standard errors, if present) and (again, if present) the corresponding asymptotic covariance of the untransformed, total (i.e. main and nuisance part) parameter.

trafo realizes partial influence curves; i.e.; we are only interested is some possibly lower dimensional smooth (not necessarily linear or even coordinate-wise) aspect/transformation \(\tau\) of the parameter \(\theta\).

To be coherent with the corresponding nuisance implementation, we make the following convention:

The full parameter \(\theta\) is split up coordinate-wise in a main parameter \(\theta'\) and a nuisance parameter \(\theta''\) (which is unknown, too, hence has to be estimated, but only is of secondary interest) and a fixed, known part \(\theta'''\).

Without loss of generality, we restrict ourselves to the case that transformation \(\tau\) only acts on the main parameter \(\theta'\) --- if we want to transform the whole parameter, we only have to assume that both nuisance parameter \(\theta''\) and fixed, known part of the parameter \(\theta'''\) have length 0.

To the implementation:

Slot trafo can either contain a (constant) matrix \(D_\theta\) or a function $$\tau\colon \Theta' \to \tilde \Theta,\qquad \theta \mapsto \tau(\theta)$$ mapping main parameter \(\theta'\) to some range \(\tilde \Theta\).

If slot value trafo is a function, besides \(\tau(\theta)\), it will also return the corresponding derivative matrix \(\frac{\partial}{\partial \theta}\tau(\theta)\). More specifically, the return value of this function theta is a list with entries fval, the function value \(\tau(\theta)\), and mat, the derivative matrix.

In case trafo is a matrix \(D\), we interpret it as such a derivative matrix \(\frac{\partial}{\partial \theta}\tau(\theta)\), and, correspondingly, \(\tau(\theta)\) as the linear mapping \(\tau(\theta)=D\,\theta\).

Author

Matthias Kohl Matthias.Kohl@stamats.de,
Peter Ruckdeschel peter.ruckdeschel@uni-oldenburg.de

See Also

Estimator

Examples

Run this code
x <- rnorm(100)
Estimator(x, estimator = mean, name = "mean")

x1 <- x; x1[sample(1:100,10)] <- NA
myEst1 <- Estimator(x1, estimator = mean, name = "mean")
samplesize(myEst1)
samplesize(myEst1, onlycomplete = FALSE)

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