Abstract
Spectral unmixing of hyperspectral images is an important issue in the fields of remote sensing. Jointly exploring the spectral and spatial information embedded in the data is helpful to enhance the consistency between mixing/unmixing models and real scenarios. This paper proposes a graph regularized nonlinear unmixing method based on the recent multilinear mixing model (MLM). The MLM takes account of all orders of interactions between endmembers, and indicates the pixel-wise nonlinearity with a single probability parameter. By incorporating the Laplacian graph regularizers, the proposed method exploits the underlying manifold structure of the pixels’ spectra, in order to augment the estimations of both abundances and nonlinear probability parameters. Besides the spectrum-based regularizations, the sparsity of abundances is also incorporated for the proposed model. The resulting optimization problem is addressed by using the alternating direction method of multipliers (ADMM), yielding the so-called graph regularized MLM (G-MLM) algorithm. To implement the proposed method on large hypersepectral images in real world, we propose to utilize a superpixel construction approach before unmixing, and then apply G-MLM on each superpixel. The proposed methods achieve superior unmixing performances to state-of-the-art strategies in terms of both abundances and probability parameters, on both synthetic and real datasets.
Highlights
Spectral unmixing (SU) has become one of the essential topics in the context of hyperspectral imagery processing
The compared unmixing methods include both the linear and nonlinear ones, namely the C-SUnSAL [6] dedicated to the linear mixing model, the so-called generalized bilinear model (GBM) [14], polynomial postnonlinear mixing model (PPNMM) [16] elaborated for the bilinear mixing model, and the aforementioned MLM [17], MLMp [18], and BNLSU [20] based on the multilinear mixing model
This result is not surprising, as the proposed graph regularized MLM (G-MLM) takes advantage of the graph information hidden in the dataset, which is more consistent with the real situation
Summary
Spectral unmixing (SU) has become one of the essential topics in the context of hyperspectral imagery processing. Hyperspectral images are captured by remote sensors over hundreds of channels within a certain wavelength range. Each such image can be viewed as a data cube, with two of its dimensions being the spatial and the third one recording the spectral information, i.e., each pixel corresponds to a spectrum vector [1]. Compared to abundant spectral information, the spatial information contained in the image is quite limited due to the low spatial resolution of sensors. It is usually assumed that each observed spectrum is mixed by several pure material signatures, termed endmembers. The aim of SU is to extract the endmembers and to determine their respective proportions, referred to as abundances [2]
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