Semiparametric inference procedure for the accelarated failure time model with interval-censored data
In this thesis new inference procedures are proposed for estimating the parameters of the accelerated failure time (AFT) model in the presence of interval-censored data. In the literature, a variety of semiparametric inference procedures are suggested by previous research for estimating the param...
Saved in:
| Main Author: | |
|---|---|
| Format: | Thesis |
| Language: | English |
| Published: |
2019
|
| Subjects: | |
| Online Access: | http://psasir.upm.edu.my/id/eprint/113988/1/113988.pdf http://psasir.upm.edu.my/id/eprint/113988/ http://ethesis.upm.edu.my/id/eprint/18046 |
| Tags: |
Add Tag
No Tags, Be the first to tag this record!
|
| Summary: | In this thesis new inference procedures are proposed for estimating the
parameters of the accelerated failure time (AFT) model in the presence of
interval-censored data. In the literature, a variety of semiparametric inference
procedures are suggested by previous research for estimating the parameters
of AFT models with censored data, and rank-based methods are popular among
all.
The main difficulty with the existing rank-based methods is that they involve
nonparametric estimation of the probability distribution of the model’s error
terms. Another problem is estimating the covariance matrix of the parameter
estimators, since the existing methods involve derivative of the hazard function
of the model’s error terms.
Considering the stated problems, the major objectives of this thesis include
developing new rank-based estimating procedures for AFT models with intervalcensored
data based on the actual rank and the expected rank estimating
functions, for both univariate and multivariate models. Other research objectives
include developing new resampling methods for estimating the covariance
matrix of the estimators based on random sampling within censoring intervals
and based on the perturbed estimating function.
The findings of this research provide two new iterative algorithms for estimating
the parameters of the AFT model with interval-censored data, and also two new
resampling techniques for estimating the covariance matrix of estimators. The
rank-based methods, estimating algorithms, and resampling techniques that are
developed do not involve the difficulties of the existing estimating procedures.
A computationally simple two-step iterative algorithm, called estimationapproximation
algorithm, is introduced for estimating the parameters of the
model on the basis of the rank estimators. Also, a one-step iterative algorithm,
called expected rank algorithm, is introduced which is more complicated than
the estimation-approximation algorithm, but more accurate. For estimating the
covariance matrix of the proposed estimators two new resampling techniques
are proposed, one based on random sampling within censoring interval and
another based on perturbed estimating function.
Inference procedures are developed for modelling multiple events intervalcensored
data through AFT models. Computational properties of the proposed
parameter estimating methods and the proposed resampling techniques are
comprehensively discussed. The proposed inference procedures are assessed
through simulation studies and their performance in applications is demonstrated
through analysing real data sets in health science and transportation.
The significance of the study from the results of the numerical analysis shows
that the proposed estimators and their corresponding resampling methods are
accurate and computationally simpler than the existing methods. The results
also imply that influential factors such as the length of censoring intervals and
the distribution of the error terms do not significantly affect their efficiency and
accuracy. The main contribution of this research is developing statistical
approaches, and introducing new algorithms and resampling methods for
analysing interval-censored data through AFT models. |
|---|