Hyperspectral image classification with discriminative manifold broad learning system

Abstract

It has been proved that hyperspectral image (HSI) classification task benefits from introducing additional spatial information. However, how to classify high-dimensional hyperspectral images under the condition of limited training samples is still a challenge. In this paper, we propose a hyperspectral image classification framework based on discriminant manifold broad learning system (DMBLS). We introduce the manifold structure and discriminant information of the data samples as prior knowledge into broad learning system (BLS), which effectively solves the problem of insufficient learning caused by BLS with limited training samples. Firstly we construct two different types of manifold structures for class modelling: the intra-class manifold structures and the inter-class ones. Secondly, we integrate these local discriminant manifold structures to build a manifold regularization framework. Finally, we add this framework to the DMBLS via minimizing the intra-class manifold structures, while maximizing the inter-class ones. And we think this operation can optimize the projection direction of output weights in the DMBLS, enhancing the discrimination ability of these weights. Experimental results on three benchmark HSI datasets show that DMBLS can effectively improve the classification accuracy of hyperspectral images under the condition of limited training samples.