An empirical study of some software fault prediction techniques for the number of faults prediction

Abstract

During the software development process, prediction of the number of faults in software modules can be more helpful instead of predicting the modules being faulty or non-faulty. Such an approach may help in more focused software testing process and may enhance the reliability of the software system. Most of the earlier works on software fault prediction have used classification techniques for classifying software modules into faulty or non-faulty categories. The techniques such as Poisson regression, negative binomial regression, genetic programming, decision tree regression, and multilayer perceptron can be used for the prediction of the number of faults. In this paper, we present an experimental study to evaluate and compare the capability of six fault prediction techniques such as genetic programming, multilayer perceptron, linear regression, decision tree regression, zero-inflated Poisson regression, and negative binomial regression for the prediction of number of faults. The experimental investigation is carried out for eighteen software project datasets collected from the PROMISE data repository. The results of the investigation are evaluated using average absolute error, average relative error, measure of completeness, and prediction at level l measures. We also perform Kruskal–Wallis test and Dunn’s multiple comparison test to compare the relative performance of the considered fault prediction techniques.