| dc.description.abstract | In this article, we present results on nonparametric regression for estimating unknown finite
population totals in a model based framework. Consistent robust estimators of finite population
totals are derived using the procedure of local polynomial regression and their robustness
properties studied (see Kikechi et al (2017), Kikechi et al (2018) and Kikechi and Simwa
(2018)). Results of the bias show that the Local Polynomial estimators dominate the Horvitz-Thompson estimator for the linear, quadratic, bump and jump populations. Further, the biases
under the model based Local Polynomial approach are much lower than those under the design
based Horvitz-Thompson approach in different populations. The MSE results show that the
Local Linear Regression estimators are performing better than the Horvitz-Thompson and
Dorfman estimators, irrespective of the model specification or misspecification. Results further
indicate that the confidence intervals generated by the model based Local Polynomial procedure
are much tighter than those generated by the design based Horvitz-Thompson method, regardless
of whether the model is specified or misspecified. It has been observed that the model based
approach outperforms the design based approach at 95% coverage rate. In terms of their
efficiency, and in comparison with other estimators that exist in the literature, it is observed that
the Local Polynomial Regression estimators are robust and are the most efficient estimators.
Generally, the Local Polynomial Regression estimators are not only superior to the popular
Kernel Regression estimators, but they are also the best among all linear smoothers including
those produced by orthogonal series and spline methods. The estimators adapt well to bias
problems at boundaries and in regions of high curvature and they do not require smoothness and
regularity conditions required by other methods such as the boundary Kernels. | en_US |
