Abstract
Target detection in hyperspectral images (HSIs) aims to distinguish target pixels from the background using knowledge gleaned from prior spectra. Most traditional methods are based on certain assumptions and utilize handcrafted classifiers. These simple models and assumptions’ failure restrict the detection performance under complicated background interference. Recently, based on the convolutional networks, many supervised deep learning detectors have outperformed the traditional methods. However, these methods suffer from unstable detection, heavy computation burden, and optimization difficulty. This paper proposes a Siamese fully connected based target detector (SFCTD) that comprises nonlinear feature extraction modules (NFEMs) and cosine distance classifiers. Two NFEMs, which extract discriminative spectral features of input spectra-pairs, are based on fully connected layers for efficient computing and share the parameters to ease the optimization. To solve the few samples problem, we propose a pseudo data generation method based on the linear mixed model and the assumption that background pixels are dominant in HSIs. For mitigating the impact of stochastic suboptimal initialization, we parallelly optimize several Siamese detectors with small computation burdens and aggregate them as ensembles in the inference time. The network ensembles outperform every detector in terms of stability and achieve an outstanding balance between background suppression and detection rate. Experiments on multiple data sets demonstrate that the proposed detector is superior to the state-of-the-art detectors.
Highlights
Hyperspectral imaging is a developing area in remote sensing in which a hyperspectral spectrometer collects hundreds of narrow contiguous bands over a wide range of the electromagnetic spectrum [1]
To solve the few samples problem, we propose a pseudo data generation method based on the linear mixed model and the assumption that background pixels are dominant in hyperspectral images (HSIs)
This paper proposes a Siamese fully connected network-based hyperspectral target detector, denoted as Siamese fully connected based target detector (SFCTD), consisting of two nonlinear feature extraction modules (NFEMs) and a cosine angle distance-based classifier
Summary
Hyperspectral imaging is a developing area in remote sensing in which a hyperspectral spectrometer collects hundreds of narrow contiguous bands over a wide range of the electromagnetic spectrum [1]. Different from target detection in natural images [2], hyperspectral target detection aims to distinguish specific target pixels from the background in given HSIs with few prior spectral information of the target, which has been the focus of the remote sensing interpretation research [3]. A higher visualization contrast-detection maps mean better background suppression capabilities. The ACE, HCEM, ECEM, TSCNTD, and proposed detector show higher visualization contrast than the SAM, MF, and CEM. The targets’ integrity of our detection results is better than that of ACE, HCEM, and ECEM. The detection results of HCEM and ECEM fail to detect the margins of the target. The false alarm detection rate of the Siamese detector with NFEMs is better than that of TSCNTD; the latter detects many background pixels as the target
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