Abstract
Pattern classification is a central problem in machine learning, with a wide array of applications, and rule-based classifiers are one of the most prominent approaches. Among these classifiers, Incremental Rule Learning algorithms combine the advantages of classic Pittsburg and Michigan approaches, while, on the other hand, classifiers using fuzzy membership functions often result in systems with fewer rules and better generalization ability. To discover an optimal set of rules, learning classifier systems have always relied on bio-inspired models, mainly genetic algorithms. In this paper we propose a classification algorithm based on an efficient bio-inspired approach, Artificial Immune Networks. The proposed algorithm encodes the patterns as antigens, and evolves a set of antibodies, representing fuzzy classification rules of ellipsoidal surface, to cover the problem space. The innate immune mechanisms of affinity maturation and diversity preservation are modified and adapted to the classification context, resulting in a classifier that combines the advantages of both incremental rule learning and fuzzy classifier systems. The algorithm is compared to a number of state-of-the-art rule-based classifiers, as well as Support Vector Machines (SVM), producing very satisfying results, particularly in problems with large number of attributes and classes.
Highlights
The immune system is a complex of cells, molecules and organs that aim at protecting the host organism from invading pathogens
We propose in this paper an algorithm applied to one of the central problems of machine learning, that of pattern classification
Most criteria are based on the common precision and accuracy metrics
Summary
The immune system is a complex of cells, molecules and organs that aim at protecting the host organism from invading pathogens. The invading agents evolve rapidly, and to combat them effectively the system must be able to generalize its recognition ability to similar, incomplete or corrupt forms of the antigen In addition to this antigen-specific response, the system must regulate the diversity of its antibody population so that they are able, as a whole, to recognize a wide array of pathogens while, at the same time, not recognize each other, in order to be able to discriminate the pathogens from the organism’s own healthy tissues. These abilities of learning, generalization, noise-tolerance and diversity regulation have made the immune system a suitable source of inspiration for a corresponding bio-inspired model, artificial immune networks. According to the Clonal Selection [1] principle, when an antigen is encountered antibodies are born to confront it
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