Abstract

Hyperspectral image (HSI) contain abundant spectral and spatial information, enabling the accurate classification of ground objects. However, many existing machine learning methods have poor performance, and some existing CNN-based methods require high computational power, which considerably limits their real-world applications. To address these issues, in this paper, we propose an alternative HSI classification method based on the stacked contractive autoencoder (SCAE) and adaptive spectral-spatial information to improve the accuracy of HSI classification. Specifically, the non-subsampled shearlet transform (NSST) with the guided filtering (NG) enhances spatial structure information. Subsequently, we present an adaptive spatial information extraction method to extract the spatial information of pixels. Furthermore, we propose an HSI classification network, called SCAE-LR, for feature extraction and classification. The SCAE is implemented to extract the adaptive spectral-spatial feature, and a logistic regression (LR) layer is employed for classification. Extensive experiments on the Indian Pines data set and the Pavia University data set demonstrate the superior performance of our method.

Highlights

  • Hyperspectral images (HSIs) are obtained by a spectral imager radiating electromagnetic waves to ground objects and collecting the signals reflected by the ground objects

  • To eliminate the edge and spatial structure blurring of HSI while making full use of their features and VOLUME 9, 2021 spatial information, this paper describes a novel HSI classification method based on image enhancement, adaptive spatial information, and the stacked contractive autoencoder (SCAE) [35]

  • A non-subsampled shearlet transform (NSST) [34] with guided filter [36] (NG) is used to enhance spatial information, the adaptive spatial information extraction method is used to extract the spatial information of unclassified pixels, and the SCAE- logistic regression (LR) network is used for adaptive spectral-spatial feature extraction and classification

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Summary

Introduction

Hyperspectral images (HSIs) are obtained by a spectral imager radiating electromagnetic waves to ground objects and collecting the signals reflected by the ground objects. Research shows that the fusion of spatial information and spectral information can improve classification accuracy [13], [14]. Li et al [15] used Markov random field post-processing on the neighborhood spatial information and combined this with logistic regression (LR) to classify HSI. The method combines the spatial coherence between adjacent pixels; all pixels in the small neighborhood are represented in the feature space, which effectively improves the separability between different data types. This method applies the same contribution to all domain pixels and makes a small contribution to the non-uniform

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