A swarm-trained k-nearest prototypes adaptive classifier with automatic feature selection for interval data

A swarm-trained k-nearest prototypes adaptive classifier with automatic feature selection for interval data

Some complex data types are capable of modeling data variability and imprecision. These data types are studied in the symbolic data analysis field. One such data type is interval data, which represents ranges of values and is more versatile than classic point data for many domains. This paper propos...

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Bibliographic Details
Published in:Neural networks Vol. 80; pp. 19 - 33
Main Authors: Silva Filho, Telmo M., Souza, Renata M.C.R., Prudêncio, Ricardo B.C.
Format: Journal Article
Language:English
Published: United States Elsevier Ltd 01-08-2016
Subjects:
Algorithms
Artificial Intelligence
Automation
Classifiers
Data processing
Feature selection
Interval data
Intervals
Learning
Models, Theoretical
Neural networks
Optimization
Prototype learning
Prototypes
Swarm optimization
Symbolic data analysis
Weighted distance
Swarm optimization
Symbolic data analysis
Feature selection
Weighted distance
Prototype learning
Interval data
Online Access:Get full text
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Summary:Some complex data types are capable of modeling data variability and imprecision. These data types are studied in the symbolic data analysis field. One such data type is interval data, which represents ranges of values and is more versatile than classic point data for many domains. This paper proposes a new prototype-based classifier for interval data, trained by a swarm optimization method. Our work has two main contributions: a swarm method which is capable of performing both automatic selection of features and pruning of unused prototypes and a generalized weighted squared Euclidean distance for interval data. By discarding unnecessary features and prototypes, the proposed algorithm deals with typical limitations of prototype-based methods, such as the problem of prototype initialization. The proposed distance is useful for learning classes in interval datasets with different shapes, sizes and structures. When compared to other prototype-based methods, the proposed method achieves lower error rates in both synthetic and real interval datasets.
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ISSN:0893-6080
1879-2782
DOI:10.1016/j.neunet.2016.04.006