Please use this identifier to cite or link to this item: https://hdl.handle.net/10321/4619
Title: Machine learning classifiers based on HoG features extracted from locomotive neutral section images
Authors: Mcineka, Christopher Thembinkosi 
Pillay, Nelendran
Keywords: Neutral section dataset;Machine learning classifiers;Histogram of oriented gradient;Computer vision;MATLAB;Confusion matrix;F1-measure
Issue Date: 27-Oct-2022
Publisher: IEEE
Source: Mcineka, C.T. and Pillay, N. 2022. Machine learning classifiers based on HoG features extracted from locomotive neutral section images. Presented at: 2022 International Conference on Engineering and Emerging Technologies (ICEET). doi:10.1109/iceet56468.2022.10007093
Journal: 2022 International Conference on Engineering and Emerging Technologies (ICEET) 
Abstract: 
This paper presents a comparative study on
machine learning algorithms for neutral section image
classification. The classifiers are trained by employing the
Histogram of Oriented Gradient features that are extracted
from the neutral section dataset [1]. A neutral section is a phase
break that is used on the Transnet freight rail system to separate
the single-phase supply from the 25kV three-phase overhead
traction supply. The 25kV is a stepped-down voltage from an
88kV three-phase supply coming from the national grid. While
the main purpose of the neutral section is to separate phase
voltages, electric locomotives can traverse through these phases
by switching On and Off. This auto-switching is possible
through induction magnets installed in between the rails and
with magnet detection sensors installed underneath the
locomotives. However, a computer vision model has been
developed, trained, and tested with a neutral section dataset
containing images having open and close markers [1]. This
paper, therefore, utilises this dataset to provide performance
comparison on several machine learning classification
algorithms viz. Decision Tree, Discriminant Analysis, Support
Vector Machine, K-Nearest Neighbors, Ensemble, Naïve Bayes,
and Convolutional Neural Network. A confusion matrix, F1-
measure and computation time are employed to measure the
performance of each classifier. The MATLAB Classification
Learner application was used to obtain the results. The results
show that the Linear Support Vector Machine performs best
when considering performance and prediction speed. The
Linear Support Vector Machine achieved a training accuracy of
93.40% with a test accuracy reaching 94% at a prediction speed
of 75 objects per second (computation time).
URI: https://hdl.handle.net/10321/4619
ISBN: 978-1-6654-9106-8
DOI: 10.1109/iceet56468.2022.10007093
Appears in Collections:Research Publications (Engineering and Built Environment)

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