eprintid: 15613
rev_number: 2
eprint_status: archive
userid: 1
dir: disk0/00/01/56/13
datestamp: 2023-11-10 03:30:14
lastmod: 2023-11-10 03:30:14
status_changed: 2023-11-10 01:59:55
type: article
metadata_visibility: show
creators_name: Balogun, A.O.
creators_name: Basri, S.
creators_name: Mahamad, S.
creators_name: Capretz, L.F.
creators_name: Imam, A.A.
creators_name: Almomani, M.A.
creators_name: Adeyemo, V.E.
creators_name: Kumar, G.
title: A novel rank aggregation-based hybrid multifilter wrapper feature selection method in software defect prediction
ispublished: pub
keywords: Classification (of information); Decision trees; Defects; Forecasting, Defect prediction models; Feature selection methods; Features selection; Local optima; Performance; Rank aggregation; Rank lists; Selection problems; Software defect prediction; Software defects, Feature extraction, algorithm; area under the curve; Bayes theorem; software, Algorithms; Area Under Curve; Bayes Theorem; Software
note: cited By 8
abstract: The high dimensionality of software metric features has long been noted as a data quality problem that affects the performance of software defect prediction (SDP) models. This drawback makes it necessary to apply feature selection (FS) algorithm(s) in SDP processes. FS approaches can be categorized into three types, namely, filter FS (FFS), wrapper FS (WFS), and hybrid FS (HFS). HFS has been established as superior because it combines the strength of both FFS and WFS methods. However, selecting the most appropriate FFS (filter rank selection problem) for HFS is a challenge because the performance of FFS methods depends on the choice of datasets and classifiers. In addition, the local optima stagnation and high computational costs of WFS due to large search spaces are inherited by the HFS method. Therefore, as a solution, this study proposes a novel rank aggregation-based hybrid multifilter wrapper feature selection (RAHMFWFS) method for the selection of relevant and irredundant features from software defect datasets. The proposed RAHMFWFS is divided into two stepwise stages. The first stage involves a rank aggregation-based multifilter feature selection (RMFFS) method that addresses the filter rank selection problem by aggregating individual rank lists from multiple filter methods, using a novel rank aggregation method to generate a single, robust, and non-disjoint rank list. In the second stage, the aggregated ranked features are further preprocessed by an enhanced wrapper feature selection (EWFS) method based on a dynamic reranking strategy that is used to guide the feature subset selection process of the HFS method. This, in turn, reduces the number of evaluation cycles while amplifying or maintaining its prediction performance. The feasibility of the proposed RAHMFWFS was demonstrated on benchmarked software defect datasets with Naïve Bayes and Decision Tree classifiers, based on accuracy, the area under the curve (AUC), and F-measure values. The experimental results showed the effectiveness of RAHMFWFS in addressing filter rank selection and local optima stagnation problems in HFS, as well as the ability to select optimal features from SDP datasets while maintaining or enhancing the performance of SDP models. To conclude, the proposed RAHMFWFS achieved good performance by improving the prediction performances of SDP models across the selected datasets, compared to existing state-of-the-arts HFS methods. © 2021 Abdullateef O. Balogun et al.
date: 2021
publisher: Hindawi Limited
official_url: https://www.scopus.com/inward/record.uri?eid=2-s2.0-85120783023&doi=10.1155%2f2021%2f5069016&partnerID=40&md5=d6b075b06b985073874288dd2ddbca1a
id_number: 10.1155/2021/5069016
full_text_status: none
publication: Computational Intelligence and Neuroscience
volume: 2021
refereed: TRUE
issn: 16875265
citation:   Balogun, A.O. and Basri, S. and Mahamad, S. and Capretz, L.F. and Imam, A.A. and Almomani, M.A. and Adeyemo, V.E. and Kumar, G.  (2021) A novel rank aggregation-based hybrid multifilter wrapper feature selection method in software defect prediction.  Computational Intelligence and Neuroscience, 2021.   ISSN 16875265