Abstract
Recently, Hyperspectral Image (HSI) classification methods based on deep learning models have shown encouraging performance. However, the limited numbers of training samples, as well as the mixed pixels due to low spatial resolution, have become major obstacles for HSI classification. To tackle these problems, we propose a resource-efficient HSI classification framework which introduces adaptive spectral unmixing into a 3D/2D dense network with early-exiting strategy. More specifically, on one hand, our framework uses a cascade of intermediate classifiers throughout the 3D/2D dense network that is trained end-to-end. The proposed 3D/2D dense network that integrates 3D convolutions with 2D convolutions is more capable of handling spectral-spatial features, while containing fewer parameters compared with the conventional 3D convolutions, and further boosts the network performance with limited training samples. On another hand, considering the existence of mixed pixels in HSI data, the pixels in HSI classification are divided into hard samples and easy samples. With the early-exiting strategy in these intermediate classifiers, the average accuracy can be improved by reducing the amount of computation cost for easy samples, thus focusing on classifying hard samples. Furthermore, for hard samples, an adaptive spectral unmixing method is proposed as a complementary source of information for classification, which brings considerable benefits to the final performance. Experimental results on four HSI benchmark datasets demonstrate that the proposed method can achieve better performance than state-of-the-art deep learning-based methods and other traditional HSI classification methods.
Highlights
Hyperspectral Image (HSI) comprise hundreds of narrow and contiguous spectral bands, and each represents the measured intensity of a narrower range of light frequencies [1]
The proposed method aims to learn an early-exiting deep learning framework for HSI classification based on 3D/2D dense networks and adaptive spectral unmixing (ASU)
The first three datasets were collected by the NASA Airborne Visible/Infrared Imaging spectrometer (AVIRIS) instrument; the last one was collected by the ROSIS-03 sensor
Summary
Hyperspectral Image (HSI) comprise hundreds of narrow and contiguous spectral bands, and each represents the measured intensity of a narrower range of light frequencies [1]. The great spectral resolution of HSI improves the capability of precisely discriminating the surface materials of interest [2,3]. Such abundant spectral information makes it beneficial to a wide range of applications, especially in some cases that cannot be directly detected by humans. For most of these applications, HSI classification has been an active area of research in remote sensing research. Because of the low spatial resolution of HSI, the spectral signature of each pixel contains a mixture of different spectra, which is caused by the multiple components that form the ground surface materials
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