lynden {DTDA}R Documentation

NPMLE computation with the second Efron-Petrosian algorithm

Description

This function computes the NPMLE for the cumulative distribution function of X observed under one-sided (right or left) and two-sided (double) truncation. It provides simple bootstrap pointwise confidence limits too. This function allows for ties in the samples of X, U and V.

Usage

lynden(X, U = NA, V = NA, error = NA, nmaxit = NA,
		 boot = TRUE, B = NA, alpha = NA,
			display.F = FALSE, display.S = FALSE)

Arguments

X

Numeric vector with the values of the target variable.

U

Numeric vector with the values of the left truncation variable. If there are no truncation values from the left, put U=NA.

V

Numeric vector with the values of the right truncation variable. If there are no truncation values from the right, put V=NA.

error

Numeric value. Maximum pointwise error when estimating the density associated to X (f) in two consecutive steps. If this is missing, it is $1e-06$.

nmaxit

Numeric value. Maximum number of iterations. If this is missing, it is set to nmaxit =100 .

boot

Logical. If TRUE (default), the simple bootstrap method is applied to lifetime distribution estimation. Pointwise confidence bands are provided.

B

Numeric value. Number of bootstrap resamples . The default NA is equivalent to B =500 .

alpha

Numeric value. (1-alpha) is the nominal coverage for the pointwise confidence intervals.

display.F

Logical. Default is FALSE. If TRUE, the estimated cumulative distribution function associated to X, (F) is plotted.

display.S

Logical. Default is FALSE. If TRUE, the estimated survival function associated to X, (S) is plotted.

Details

The NPMLE for the cumulative distribution function is computed by the second algorithm proposed in Efron and Petrosian (1999). This is an iterative algorithm which converges to the NMPLE after a number of iterations. If the second (respectively third) argument is missing, the Lynden-Bell estimator for right-truncated (respectively left-truncated) data is obtained. Note that individuals with NAs in the three first arguments will be automatically excluded.

Value

A list containing the following values:

time

The timepoint on the curve.

n.event

The number of events that ocurred at time t.

events

The total number of events.

NJ

The number of individuals in risk considering the left truncation times.

density

The estimated density values.

cumulative.df

The estimated cumulative distribution values.

truncation.probs

The probability of X falling into each truncation interval.

hazard

The estimated hazard values.

S0

error reached in the algorithm.

Survival

The estimated survival values.

n.iterations

The number of iterations used by this algorithm.

B

Number of bootstrap resamples computed.

alpha

The nominal level used to construct the confidence intervals.

upper.df

The estimated upper limits of the confidence intervals for F.

lower.df

The estimated lower limits of the confidence intervals for F.

upper.Sob

The estimated upper limits of the confidence intervals for S.

lower.Sob

The estimated lower limits of the confidence intervals for S.

sd.boot

The bootstrap standard deviation of F estimator.

boot.repeat

The number of resamples done in each bootstrap call to ensure the existence and uniqueness of the bootstrap NPMLE.

Author(s)

Carla Moreira, Jacobo de Uña-Álvarez and Rosa Crujeiras

References

Efron B and Petrosian V (1999) Nonparametric methods for doubly truncated data. Journal of the American Statistical Association 94, 824-834.

Lynden-Bell D (1971) A method of allowing for known observational selection in small samples applied to 3CR quasars. Monograph National Royal Astronomical Society 155, 95-118.

See Also

efron.petrosian

Examples


#  Generating data which are doubly truncated

set.seed(4321)

n<-25
X<-runif(n,0,1)
U<-runif(n,0,0.25)
V<-runif(n,0.75,1)

for (i in 1:n){
	while (X[i]<U[i]|X[i]>V[i]){
	U[i]<-runif(1,0,0.25)
	X[i]<-runif(1,0,1)
	V[i]<-runif(1,0.75,1)
					   }
		 }
res<-lynden(X=X, U=U, V=V, boot=FALSE, display.F=TRUE, display.S=TRUE)

# Generating data which are right truncated

set.seed(4321)

n<-25
X<-runif(n,0,1)
V<-runif(n,0.75,1)

for (i in 1:n){
	while (X[i]>V[i]){
	X[i]<-runif(1,0,1)
	V[i]<-runif(1,0.75,1)
			     }
		 }
res<-lynden(X=X,U=NA, V=V, boot=FALSE)



[Package DTDA version 3.0.1 Index]