An Effective Multiresolution Hierarchical Granular Representation Based Classifier Using General Fuzzy Min-Max Neural Network

Motivated by the practical demands for simplification of data toward being consistent with human thinking and problem-solving, as well as tolerance of uncertainty, information granules are becoming important entities in data processing at different levels of data abstraction. This article proposes a method to construct classifiers from multiresolution hierarchical granular representations using hyperbox fuzzy sets. The proposed approach forms a series of granular inferences hierarchically through many levels of abstraction. An attractive characteristic of our classifier is that it can maintain a high accuracy in comparison to other fuzzy min-max models at a low degree of granularity based on reusing the knowledge learned from lower levels of abstraction. In addition, our approach can reduce the data size significantly as well as handle the uncertainty and incompleteness associated with data in real-world applications. The construction process of the classifier consists of two phases. The first phase is to formulate the model at the greatest level of granularity, while the later stage aims to reduce the complexity of the constructed model and deduce it from data at higher abstraction levels. Experimental analyses conducted comprehensively on both synthetic and real datasets indicated the efficiency of our method in terms of training time and predictive performance in comparison to other types of fuzzy min-max neural networks and common machine learning algorithms.

Automated summary

Motivated by the practical demands, this article proposes a method to construct classifiers using hyperbox fuzzy sets, maintaining high accuracy through granular inferences and reducing data size significantly. The approach is efficient in terms of training time and predictive performance compared to other fuzzy min-max models and common machine learning algorithms.