Abstract
Band redundancy and limitation of labeled samples restrict the development of hyperspectral image classification (HSIC) greatly. To address the earlier issues, the classification models such as subspace-based support vector machines, which have gained a certain advance but mainly concentrate on the dimensionality reduction and ignore the augmentation of training samples. In fact, these two issues are equally important for improving the performance of classification, and should be addressed simultaneously. Therefore, this article proposes a novel method named extended subspace projection upon sample augmentation based on global spatial and local spectral similarity (GLSC) for HSIC, which takes both sample augmentation and dimensionality reduction into consideration. Specifically, it first exploits the GLSC to enlarge the original labeled sample set, which allows HSIC to obtain more prior information. Then, the augmented samples and the original labeled samples are combined to construct the extended subspace, which is more comprehensive to reflect the real situation of the ground objects. Finally, the original HSI is projected to the subspace and classified by the neighborhood activity degree-driven representation-based classifier. Experimental results on three real hyperspectral datasets demonstrate the practicality and effectiveness of the proposed method for HSIC tasks.
Highlights
REMOTE sensing is a comprehensive technology used for earth observation
We proposed a new method named Extended Subspace Projection upon Sample Augmentation based on Global Spatial and Local Spectral Similarity (ESSA-GLSC) for hyperspectral remote sensing image (HSI) classification (HSIC), which takes both dimensionality reduction and sample augmentation into consideration
From the perspective of the overall accuracy (OA) and the class-dependent accuracy (CA), Section IV-C presents the analysis of the classification results of different methods mentioned above
Summary
REMOTE sensing is a comprehensive technology used for earth observation. Hyperspectral remote sensing is such a technique characterized by imaging land surface at numerous spectral bands [1]-[3]. With the high spectral resolution, hyperspectral remote sensing image (HSI) enables a complete spectral diagnosis of ground objects, allowing a fine classification of land cover and land use classes [4], [5]. Maximum variance principal component analysis (MVPCA) [11], [12] and constrained band selection (CBS) [13], [14] are two classic methods that have been proved effective in band selection. Feature extraction is another way of dimensionality reduction. Due to the existence of mixed pixels and intra-class spectral variation [23], the effectiveness of this algorithm is affected by the selection of training samples
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
