Hyperspectral Unmixing with Gaussian Mixture Model and Spatial Group Sparsity

Qiwen Jin,Chenhong Sui,Jun Huang,Hao Li,Yong Ma,Xiaoguang Mei,Erting Pan,Fan Fan

doi:10.3390/rs11202434

Qiwen Jin, Chenhong Sui + Show 6 more

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https://doi.org/10.3390/rs11202434

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Abstract

In recent years, endmember variability has received much attention in the field of hyperspectral unmixing. To solve the problem caused by the inaccuracy of the endmember signature, the endmembers are usually modeled to assume followed by a statistical distribution. However, those distribution-based methods only use the spectral information alone and do not fully exploit the possible local spatial correlation. When the pixels lie on the inhomogeneous region, the abundances of the neighboring pixels will not share the same prior constraints. Thus, in this paper, to achieve better abundance estimation performance, a method based on the Gaussian mixture model (GMM) and spatial group sparsity constraint is proposed. To fully exploit the group structure, we take the superpixel segmentation (SS) as preprocessing to generate the spatial groups. Then, we use GMM to model the endmember distribution, incorporating the spatial group sparsity as a mixed-norm regularization into the objective function. Finally, under the Bayesian framework, the conditional density function leads to a standard maximum a posteriori (MAP) problem, which can be solved using generalized expectation-maximization (GEM). Experiments on simulated and real hyperspectral data demonstrate that the proposed algorithm has higher unmixing precision compared with other state-of-the-art methods.

Highlights

Over the past few decades, the rich spatial–spectral joint information of hyperspectral imaging (HSI) has greatly improved the sensing ability of remote sensing images
First, we describe the specific steps in implementing the superpixel segmentation, introduce the Gaussian mixture model (GMM) unmixing based on the spatial group sparsity
For the GMM and SGSGMM algorithms, as the number of components Kj will affect the calculation rate of the algorithm, to accelerate the computation time of iteration, the original data is reduced to 10 dimensions by Principal Component Analysis (PCA) as input

Summary

Introduction

Over the past few decades, the rich spatial–spectral joint information of hyperspectral imaging (HSI) has greatly improved the sensing ability of remote sensing images. Limited by the spatial resolution of the instrument, atmospheric mixing effects, and the complex natural surface, a single pixel always contains more than one spectrum of features, resulting in a “mixed pixel” phenomenon. This brings great difficulty to the accurate interpretation and recognition of hyperspectral image contents. The spectral unmixing (SU), which refers to identify the proportion (abundance) of the basic constituent spectra (endmembers) in mixed pixels at the subpixel level, has been a major issue in hyperspectral remote sensing applications, and has recently been extensively investigated [9,10,11,12,13].

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