Abstract
Metric learning-based methods, which yield great performance and show considerable potential to improve the performance of hyperspectral image processing, aim to calculate the Mahalanobis distance metric matrix. In this article, we proposed a symmetric information-theoretic metric learning (SITML) method for hyperspectral target detection. The SITML algorithm is designed based on the classical information-theoretic metric learning (ITML) and, minimizes the differential Kullback–Leibler (KL) divergence. To enhance both of the detection performance and the generalization ability, we build metric spaces from the neighborhood of training samples to preserve the local discriminative information. Then, we conduct local pairwise constraints to maximize the Jeffery divergence (also named the symmetric KL divergence) of two multivariate Gaussian distributions to solve the problem of an asymmetric KL divergence. Finally, we use a closed-form solution to solve the optimization problem. Intensive experiments on three hyperspectral datasets indicate that SITML outperforms the classical ITML algorithm and other state-of-the-art target detection methods.
Highlights
HYPERSPECTRAL remote sensing covers the reflectance of a material’s surface over hundreds of contiguous spectral wavelength bands
Constrained energy minimization (CEM) is a linear filter, in which the amount of spectral output energy is minimized under the same constraints [12, 13]
Kernel Orthogonal subspace projection (OSP) maps the original space into the kernel space for handling with the problem of linearly inseparability [19, 20]
Summary
HYPERSPECTRAL remote sensing covers the reflectance of a material’s surface over hundreds of contiguous spectral wavelength bands. Each material has a specific wave reflectance, which can be used for distinguishing different materials [1,2,3,4,5,6,7] Based on this spectral characteristic, hyperspectral target detection, the goal of which is to distinguish pixels as target pixels or background ones with prior information, has attracted much interest in the remote sensing processing field and has many applications, such as military reconnaissance and striking, crop yield estimation, and mineralogy resource investigation [8,9,10]. Adaptive coherence/cosine estimator (ACE), which is considered as one of the best hyperspectral target detection algorithms, is derived from generalized likelihood ratio test [14,15,16]. ACE(AUC=0.9974) OSP(AUC=0.9985) TCIMF(AUC=0.9978) LMNN(AUC=0.9146) XQDA(AUC=0.9948) ITML(AUC=0.9993) SITML(AUC=1)
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