Multi-Prior Graph Autoencoder with Ranking-Based Band Selection for Hyperspectral Anomaly Detection

Hyperspectral anomaly detection (HAD) is an important technique used to identify objects with spectral irregularity that can contribute to object-based image analysis. Latterly, significant attention has been given to HAD methods based on Autoencoders (AE). Nevertheless, due to a lack of prior infor...

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Bibliographic Details
Published inRemote sensing (Basel, Switzerland) Vol. 15; no. 18; p. 4430
Main Authors Wang, Nan, Shi, Yuetian, Li, Haiwei, Zhang, Geng, Li, Siyuan, Liu, Xuebin
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.09.2023
Subjects
Anomalies
autoencoder
band selection
Collaboration
deep learning
Detectors
Electric waves
Electromagnetic radiation
Electromagnetic waves
Electromagnetism
hyperspectral anomaly detection
Image analysis
Image processing
Image segmentation
Modelling
Normal distribution
Ranking
Rankings
Reconstruction
Regularization
Remote sensing
Semantics
Sensors
Sparsity
Weight
Taiwan
California
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Summary:Hyperspectral anomaly detection (HAD) is an important technique used to identify objects with spectral irregularity that can contribute to object-based image analysis. Latterly, significant attention has been given to HAD methods based on Autoencoders (AE). Nevertheless, due to a lack of prior information, transferring of modeling capacity, and the “curse of dimensionality”, AE-based detectors still have limited performance. To address the drawbacks, we propose a Multi-Prior Graph Autoencoder (MPGAE) with ranking-based band selection for HAD. There are three main components: the ranking-based band selection component, the adaptive salient weight component, and the graph autoencoder. First, the ranking-based band selection component removes redundant spectral channels by ranking the bands by employing piecewise-smooth first. Then, the adaptive salient weight component adjusts the reconstruction ability of the AE based on the salient prior, by calculating spectral-spatial features of the local context and the multivariate normal distribution of backgrounds. Finally, to preserve the geometric structure in the latent space, the graph autoencoder detects anomalies by obtaining reconstruction errors with a superpixel segmentation-based graph regularization. In particular, the loss function utilizes ℓ2,1-norm and adaptive salient weight to enhance the capacity of modeling anomaly patterns. Experimental results demonstrate that the proposed MPGAE effectively outperforms other state-of-the-art HAD detectors.
ISSN:2072-4292
2072-4292
DOI:10.3390/rs15184430