Abstract
Multisource remote sensing data contain complementary information on land covers, but fusing them is a challenging problem due to the heterogeneous nature of the data. This article aims to extract and integrate information from hyperspectral image (HSI) and light detection and ranging (LiDAR) data for land cover classification. As there is a scarcity of a large number of training samples for remotely sensed hyperspectral and LiDAR data, in this article, we propose a model, which is able to perform impressively using a limited number of training samples by extracting effective features representing different characteristics of objects of interest from these two complementary data sources (HSI and LiDAR). A novel feature extraction method named inverse coefficient of variation (ICV) is introduced for HSI, which considers the Gaussian probability of neighborhood between every pair of bands. We, then, propose a two-stream feature fusion approach to integrate the ICV feature with several features extracted from HSI and LiDAR data. We incorporate a fusion unit named canonical correlation analysis as a basic unit for fusing two different sets of features within each stream. We also incorporate the concept of ensemble classification where the features produced by two-stream fusion are distributed into subsets and transformed to improve the feature quality. We compare our method with the existing state-of-the-art methods, which are based on deep learning or handcrafted feature extraction or using both of them. Experimental results show that our proposed approach performs better than other existing methods with a limited number of training samples.
Highlights
E XTRACTION and integration of useful information from multiple data sources in an effective way remains an open challenge for automatic remote sensing data interpretation
In Stream 1 of two-stream fusion, the overall accuracy (OA) is increased by 9.77% compared to the combination HS+differential attribute profile (DAP)(HS) when canonical correlation analysis (CCA) fusion is done between hyperspectral image (HSI) spectral responses and DAP features derived from HSI and light detection and ranging (LiDAR)
In Stream 2 of two-stream fusion, CCA fusion between inverse coefficient of variation (ICV) responses and other DAP features derived from ICV and LiDAR improves OA by 11.91% compared to the combination ICV+DAP(ICV)
Summary
E XTRACTION and integration of useful information from multiple data sources in an effective way remains an open challenge for automatic remote sensing data interpretation. Most recent methods used raw spectral features from HSI, digital surface model (DSM) and intensity from LiDAR data, Manuscript received July 8, 2019; revised October 22, 2019 and December 2, 2019; accepted December 19, 2019. Morphological attribute profiles (APs) from HSI and DSM already proved its effectiveness as spatial features [4]–[6]. An effective way for deriving morphological APs is to apply it on the first few principal components (PCs) of HSI [4], [6]. New spatial features such as extinction profile [3], [7], [8] and pseudo-waveforms [9] have been used for land cover classification. When the efficiency of feature extraction is concerned, Bao et al [10] extracted derivatives of spectral reflectance signatures from HSI, which captured sharp changes between neighboring bands with little cost of computation
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More From: IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing
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