Spatial–Spectral Joint Hyperspectral Anomaly Detection Based on a Two-Branch 3D Convolutional Autoencoder and Spatial Filtering

Abstract: Hyperspectral anomaly detection (HAD) is an important application of hyperspectral images (HSI) that can distinguish anomalies from background in an unsupervised manner. As a common unsupervised network in deep learning, autoencoders (AE) have been widely used in HAD and can highlight anomalies by reconstructing the background. This study proposed a novel spatial–spectral joint HAD method based on a two-branch 3D convolutional autoencoder and spatial filtering. We used the two-branch 3D convolutional autoencod… Show more

“…As for the inter-band correlation, SSRICAD [38] adopts the approach of spatial-spectral joint reconstruction. In [39], a novel two-branch AE adopts 3D convolution to excavate the spectral-spatial information of the HSI [39]. Due to the lack of prior knowledge in HAD, some models leverage low-rank representation to guide the AE optimization, such as DeepLR [40], LELRP-AD [41], DFAN [42] and DLRSPs-DAEs [43].…”

Hyperspectral Anomaly Detection via Low-Rank Representation with Dual Graph Regularizations and Adaptive Dictionary

“…As for the inter-band correlation, SSRICAD [38] adopts the approach of spatial-spectral joint reconstruction. In [39], a novel two-branch AE adopts 3D convolution to excavate the spectral-spatial information of the HSI [39]. Due to the lack of prior knowledge in HAD, some models leverage low-rank representation to guide the AE optimization, such as DeepLR [40], LELRP-AD [41], DFAN [42] and DLRSPs-DAEs [43].…”

Hyperspectral Anomaly Detection via Low-Rank Representation with Dual Graph Regularizations and Adaptive Dictionary

In situ grape ripeness estimation via hyperspectral imaging and deep autoencoders