Abstract
With the development of sensor technology, fusion of multiple remote sensors has aroused wide attention in the earth observation area. In this article, we propose to integrate the complementary information of hyperspectral image (HSI) and infrared image (IFI) based on mathematical morphological methods. HSI contains rich spectral information and spatial information, but the operation methods using only hyperspectral data are still subject to many restrictions. IFI can capture infrared rays radiated in the object, but it has no advantage in dealing with complex terrain classification. HSI and IFI can acquire different information of objects, and the information between these two kinds of data has great complementarity. In order to make full use of the information provided by HSI and IFI, this article proposes an HSI and IFI collaborative classification framework based on a Threshold-based Local Contain Profile (TLCP), where TLCP is our new design for suppressing interferes within spatial extractions. Specifically, the spatial information of HSI and IFI is extracted by TLCP, and then, these features are integrated and fed into the support vector machine for object classification. Experimentally, we compare the proposed method with the existing LCP and EP and evaluate the collaborative framework using GF5 satellite data collected over Hebei Province in China. Final results demonstrated the effectiveness of the proposed method.
Highlights
W ITH the development of remote sensing (RS) technology, a large amount of data is available, making remarkable progress in various applications [1]
Morphological features of five attributes of the data are extracted using Threshold-based Local Contain Profile (TLCP), EP, and LCP, and support vector machine (SVM) is utilized as the classifier for obtaining the final classification result
An hyperspectral image (HSI) and infrared image (IFI) collaborative framework based on TLCP was proposed
Summary
W ITH the development of remote sensing (RS) technology, a large amount of data is available, making remarkable progress in various applications [1]. In [6], multiscale superpixel segmentation and subspace-based support vector machine (SVM) are fused together to integrate spatial information for the HSI classification, and it shows effectiveness and reliability in the earth observation task. In [8], a domain adaptive strategy is proposed to adjust the semantic segmentation network through adversarial learning, which solves the problem of fine-grained mapping of urban villages (UVs) from satellite images, and adaptively obtaining similar outputs for input images from different domains. This strategy can significantly improve the pixel-level mapping of UVs
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