An Algorithm for Ordinal Classification Based on Pairwise Comparison

Ordinal classification problems are applied in many fields. In the field of multivariate statistical analysis, these tasks are referred to as ordinal regression problems. In the field of management decision-making, they are known as multi-criteria decision analyses or sorting problems. This paper in...

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Bibliographic Details
Published in:Journal of classification 2020-04, Vol.37 (1), p.158-179
Main Authors: Yang, Yunli, Chen, Baiyu, Yang, Zhouwang
Format: Article
Language:English
Subjects:
Algorithms
Bioinformatics
Classification
Computation
Decision analysis
Decision making
Engineering
Error correction
Marketing
Mathematics and Statistics
Multiple criterion
Multivariate statistical analysis
Numerical prediction
Pattern Recognition
Psychometrics
Regression analysis
Signal,Image and Speech Processing
Sorting algorithms
Statistical analysis
Statistical methods
Statistical Theory and Methods
Statistics
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Summary:Ordinal classification problems are applied in many fields. In the field of multivariate statistical analysis, these tasks are referred to as ordinal regression problems. In the field of management decision-making, they are known as multi-criteria decision analyses or sorting problems. This paper introduces the PairCode algorithm for ordinal classification with small sample sizes, which is based on a pairwise comparison strategy. In addition, this work outlines how to use pairwise comparisons to transform ordinal classifications into disordered regressions and how to transform the results of disordered regressions back to their original ordinal categories. Some effective strategies have been put forward, such as designing a class-label encoding matrix for the pairwise comparison, balancing samples, training classifiers, and predicting new samples. In numerical experiments, our algorithm (PairCode) is compared with the ordinal logistic regressions (LogisticOP) (Hu et al., IEEE Transactions on Knowledge and Data Engineering, 24 (11), 2052–2064, 2012 ; Harrell 2015b ), SVMOP (Gutiérrez et al., IEEE Transactions on Knowledge and Data Engineering, 28 (1), 127–146, 2016 ; Leathart et al. 2016 ), SVORIM (Chu and Sathiya Keerthi, Neural Computation, 19 (3), 792–815 2007 ; Gutiérrez et al., IEEE Transactions on Knowledge and Data Engineering, 28 (1), 127–146, 2016 ), SVOREX (Chu and Sathiya Keerthi, Neural Computation, 19 (3), 792–815 2007 ; Gutiérrez et al., IEEE Transactions on Knowledge and Data Engineering, 28 (1), 127–146, 2016 ), and ELMOP (Deng et al., Neurocomputing, 74 (1), 447–456, 2010 ; Gutiérrez et al., IEEE Transactions on Knowledge and Data Engineering, 28 (1), 127–146, 2016 ). The results show that the PairCode algorithm performs better and is relatively stable as reflected by the correct classification rate (CCR), the mean absolute error (MAE), and the maximum MAE value (MMAE). However, the computing speed of the PairCode algorithm for classification is slightly slow and therefore warrants further study to improve the speed.
ISSN:0176-4268
1432-1343
DOI:10.1007/s00357-019-9311-4