Abstract
Third-order tensors have been widely used in hyperspectral remote sensing because of their ability to maintain the 3-D structure of hyperspectral images. In recent years, hyperspectral unmixing algorithms based on tensor factorization have emerged, but these decomposition processes may be inconsistent with physical mechanism of unmixing. To solve this problem, this article proposes a sparse and low-rank constrained tensor factorization unmixing algorithm based on a matrix-vector nonnegative tensor factorization (MV-NTF) framework. Considering the fact that each component tensor obtained by the image decomposition contains only one endmember and the corresponding abundance matrix has sparse property, a sparse constraint is imposed to ensure the accuracy of abundance maps. Since abundance maps also have low-rank attribute, in order to avoid the strict low-rank constraint in the original MV-NTF framework, a low-rank tensor regularization is introduced to flexibly express the low-rank characteristics of the abundance tensors, making the resulting abundance maps more in line with the actual scene. Then, the optimization problem is solved by using the alternating direction method of multipliers. In experiments, simulated datasets are adopted to demonstrate the effectiveness of the sparse and low-rank constraints of the proposed algorithm, and real datasets from different sensors and different scenarios are used to verify its applicability.
Highlights
H YPERSPECTRAL remote sensing technology can effectively distinguish objects that cannot be detected in the traditional multispectral remote sensing technology, making the application of remote sensing technology more refined [1]
The results show that this constraint effectively improves the accuracy of hyperspectral unmixing
A new tensor factorization method sparse and low-rank tensor constrained factorization (SPLRTF) was proposed for hyperspectral unmixing
Summary
H YPERSPECTRAL remote sensing technology can effectively distinguish objects that cannot be detected in the traditional multispectral remote sensing technology, making the application of remote sensing technology more refined [1]. MV-NTF algorithm decomposes a hyperspectral image into several component tensors, each of which is the outer product of matrix and vector, representing endmember and abundance [32], respectively Based on this model, Xiong et al introduced the idea of super pixel into MV-NTF, where both global and local information were taken into consideration, avoiding noise interference [33]. Under the framework of MV-NTF unmixing model, considering that each pixel has only a few types of endmembers and inherent data structural information, the proposed method will focus on imposing low-rank and sparse constraints in the estimation process in order to obtain accurate endmember spectra and fractional abundance results.
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