Hyperspectral Anomaly Detection Using Deep Learning: A Review
Abstract
:1. Introduction
1.1. Hyperspectral Image and Applications
1.2. Anomaly Detection
1.3. Hyperspectral Anomaly Detection
1.4. Contributions and Structure
2. Datasets
- (1)
- San Diego Dataset: The real hyperspectral data of the San Diego area collected by AVIRIS sensor. SDD-1 has 189 spectral bands, and the image data space pixel size is 100 × 100. The hangar, tarmac, and soil are the main backgrounds, and three airplanes and 134 spatial pixels are considered anomalies. SDD-2 has 193 spectral bands, spatial pixels 100 × 100, beach and seawater as the main background, and man-made objects with 202 spatial pixels in the water are regarded as anomalies.
- (2)
- Cat Island Dataset: Collected by AVIRIS sensor, it contains 193 spectral bands and the spatial pixels are 100 × 100. The main background is seawater and islands, and a ship with 19 spatial pixels is considered anomalous.
- (3)
- Pavia Dataset: the scene of Pavia city in northern Italy collected by ROSIS-03 sensor. Including 102 spectral bands, the image scene covers 150 × 150 pixels, the spatial resolution is 1.3 m/pixel, and the main background is bridge and water. There are some vehicles on the bridge accounting for a total of 68 pixels. The spectral characteristics of these pixels are different from the background, thus they are regarded as anomalies.
- (4)
- HYDICE Urban Dataset: an urban scene in California, the image size is 80 × 100, and the original data has 210 bands. After removing noise and water absorption, 162 bands are generally left for subsequent processing and analysis. The ground features include roads, roofs, grasslands, and trees. Among them, 21 pixels were considered abnormal.
- (5)
- GulfPort Dataset: Images of GulfPort area in the United States collected by AVIRIS sensors. Contains 191 spectral bands, the range is 400–2500 nm, the spatial pixel is 100 × 100, and the spatial resolution is 3.4 m. Three planes of different proportions on the ground are regarded as anomalies.
- (6)
- Los Angeles Dataset: The image of Los Angeles urban area collected by AVIRIS sensor, including 205 spectral bands, spatial pixels of 100 × 100, and spatial resolution of 7.1 m. Among them, LA-1 occupies 272 pixels of buildings and LA-2 occupies 232 pixels of houses are considered abnormal.
- (7)
- Wuhan University: The ultra-macro airborne hyperspectral imaging spectrometer (NANO-Hyperspec) loaded by UAV drones contains 270 bands and 4000 × 600 spatial pixels, which is much larger than the commonly used hyperspectral anomaly detection data set. Among them, there are 1122 abnormal pixels in Station and 1510 abnormal pixels in Park.
- (8)
- Texas Coast Dataset: The US Texas coast image collected by the AVIRIS sensor, including Texas coast-1, contains 204 spectral bands, spatial pixels 100 × 100, and spatial resolution 17.2 m, 67 pixels of which are regarded as anomalies. Texas coast-2, contains 207 spectral bands, spatial pixels 100 × 100, spatial resolution 17.2 m, vehicles in the parking lot are marked as abnormal.
- (9)
- Bay Champagne Dataset: The Vanuatu region image collected by the AVIRIS sensor contains 188 spectral bands, spatial pixels 100 × 100, and a spatial resolution of 4.4 m. Among them, 13 pixels are regarded as anomalies, accounting for 0.13% of the entire scene.
- (10)
- EI Segundo Data: The image of the El Segundo area in the United States collected by the AVIRIS sensor contains 224 spectral bands, spatial pixels 250 × 300, and spatial resolution 7.1 m. The data set consists of oil refinery areas, residential areas, parks, and campuses, among which oil storage tanks and towers are considered anomalies.
- (11)
- Grand Island: Collected by the AVIRIS sensor, it contains 224 spectral channels with a spatial resolution of 4.4 m, and man-made objects in the water are regarded as anomalies.
- (12)
- Cuprite and Moffett: Collected by the AVIRIS sensor, it contains 224 bands, the spatial size is 512 × 512, and the spatial resolution is 20 m. Furthermore, 46 and 59 pixels are regarded as anomalies, respectively.
3. Machine Learning Model in HSI-AD
3.1. Traditional Methods
- (1)
- Abnormal spectral features are easy to distinguish in the spectral domain;
- (2)
- Abnormalities usually appear in smaller areas;
3.2. Deep Learning-Based Methods
3.2.1. CNN
3.2.2. Autoencoder
3.3. DBN
3.4. GAN
3.5. RNN and LSTM
4. HSI-AD Based on Deep Learning
4.1. Model-Based Network
4.1.1. Based on Convolutional Neural Network
4.1.2. Based on Autoencoder
- (1)
- Can the detection model applied to natural images be directly extended to HAD tasks without any background or abnormal training samples?
- (2)
- If not, how to design the network architecture in a spectrum-driven way to take advantage of the inherent spectral characteristics without supervision.
- (3)
- Is it possible to improve the detection performance by emphasizing the discriminative constraints on the feature extraction network?
4.1.3. GAN
4.1.4. Recurrent Neural Network (RNN)
4.1.5. Deep Belief Network (DBN)
4.1.6. Based on Long and Short-Term Memory Network
4.2. Based on Hybrid Network
4.2.1. Manifold Learning Constrained Autoencoder Network
4.2.2. Semi-Supervised Background Estimation Based on Adversarial Learning and Autoencoder
4.2.3. Redundant Difference Network
4.2.4. Adversarial Autoencoder Network Based on LSTM
4.3. Other Networks
4.3.1. End to End
4.3.2. Deep Learning Converted to Low-Rank Representation
5. Performance Evaluation Index for Anomaly Detection
5.1. Based on Convolutional Neural Network
5.2. Box Plot
6. Performance Comparison
7. Challenges
- (1)
- Using feature extraction or band selection to reduce dimensionality, features may be lost to a certain extent.
- (2)
- Affected by noise and interference, it is difficult to meet the requirements of high detection accuracy and low false alarm rate using high-dimensional hyperspectral anomaly detection. In addition, there are problems with insufficient samples and imbalances.
- (3)
- Real-time anomaly detection can not only detect ground objects in real time, but can also effectively relieve the pressure of data storage. Therefore, the military defense and civilian fields have an urgent need for real-time processing. The current real-time processing algorithm results are not ideal. How to introduce new methods, such as GPU, is a key issue for real-time processing.
- (4)
- HSI contains abundant spectral information, but due to the influence of illumination, scattering, and other problems, it is easily disturbed by noise during the imaging process. Therefore, it is difficult for the original spectral features to effectively show the separability of the background and the abnormal target.
- (5)
- There are many methods for anomaly detection, but there are few practical applications.
- (6)
- UAV-borne hyperspectral data has a higher resolution, and the large amount of existing UAVs data should be fully utilized.
- (7)
- Deep learning hyperspectral anomaly detection under the condition of few samples is still a challenging problem.
8. Future Directions
- (1)
- According to HSI’s own characteristics, combined with the advantages of end-to-end and high-level deep feature extraction of deep learning models, it can be combined with manifold learning, sparse representation, graph learning, and other theories to consider designing new deep learning models to improve performance.
- (2)
- Combining the characteristics of HSI, design a space-spectrum joint deep network.
- (3)
- In terms of model training, transfer learning, weakly supervised learning, self-supervised learning, etc. can be introduced, and a small number of samples can be used to implement deep learning network training and optimization.
- (4)
- Focus on the collaborative learning of multi-modal and multi-temporal data.
- (5)
- Real-time anomaly detection.
9. Conclusions
Author Contributions
Funding
Data Availability Statement
Conflicts of Interest
Appendix A
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Dataset | Sensor | Spectral Band | Size | Resolution | Abnormal |
---|---|---|---|---|---|
San Diego | AVIRIS | SDD-1:189 SDD-2:193 | 100 × 100 | 7.5 m | SDD-1:3 planes and 134 pixels SDD-2: 202-pixel artificial object |
Cat Island | AVIRIS | 193 | 100 × 100 | 17.2 m | One ship: 19 pixels |
Pavia | ROSIS-03 | 102 | 150 × 150 | 1.3 m | Vehicle: 68 pixels |
HYDICE Urban | Hydice | 210 | 80 × 100 | 3 m | 21 pixels |
GulfPort | AVIRIS | 191 | 100 × 100 | 3.4 m | Three airplanes of different proportions with 68 pixels |
Los Angeles | AVIRIS | 205 | 100 × 100 | 7.1 m | LA-1: buildings with 272 pixels LA_2: houses with 232 pixels |
Texas Coast | AVIRIS | TC-1:204 TC-2:207 | 100 × 100 | 17.2 m | TC-1: 67 pixels TC-2: Vehicle |
Bay Champagne | AVIRIS | 188 | 100 × 100 | 4.4 m | Vehicle |
EI Segundo | AVIRIS | 224 | 250 × 300 | 7.1 m | Oil storage tanks and towers |
WHU-Hi | NANO-Hyperspec (Airborne) | Station:270 Park:270 | 4000 × 600 | 0.04 m 0.08 m | 1122 pixels 1510 pixels |
Grand Island | AVIRIS | 224 | 300 × 480 | 4.4 m | Man-made objects in water |
Cuprite | AVIRIS | 224 | 512 × 512 | 20 m | 46 pixels |
Moffett | AVIRIS | 224 | 512 × 512 | 20 m | 59 pixels |
Dataset | RX Statistics | CRD Representation | TBASD Tensor | DeCNN CNN | SCAAE AE | BASGAN GAN | SSFE DBN | EDLAD LSTM |
---|---|---|---|---|---|---|---|---|
HYDICE Urban | 0.9857 | 0.9956 | - | 0.9976 | 0.9968 | 0.9987 | 0.9985 | - |
San Diego | 0.909 | 0.9880 | - | 0.9932 | 0.9852 | 0.9954 | 0.9946 | 0.9917 |
Pavia | 0.9543 | 0.9862 | 0.9828 | 0.9994 | 0.9992 | - | - | - |
Dataset | RX Statistics | CRD Representation | TBASD Tensor | DeCNN CNN | SCAAE AE | BASGAN GAN | SSFE DBN | EDLAD LSTM |
---|---|---|---|---|---|---|---|---|
HYDICE Urban | 0.9857 | 0.9956 | - | 0.9976 | 0.9968 | 0.9987 | 0.9985 | - |
San Diego | 0.909 | 0.9880 | - | 0.9932 | 0.9852 | 0.9954 | 0.9946 | 0.9917 |
Pavia | 0.9543 | 0.9862 | 0.9828 | 0.9994 | 0.9992 | - | - | - |
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Hu, X.; Xie, C.; Fan, Z.; Duan, Q.; Zhang, D.; Jiang, L.; Wei, X.; Hong, D.; Li, G.; Zeng, X.; et al. Hyperspectral Anomaly Detection Using Deep Learning: A Review. Remote Sens. 2022, 14, 1973. https://doi.org/10.3390/rs14091973
Hu X, Xie C, Fan Z, Duan Q, Zhang D, Jiang L, Wei X, Hong D, Li G, Zeng X, et al. Hyperspectral Anomaly Detection Using Deep Learning: A Review. Remote Sensing. 2022; 14(9):1973. https://doi.org/10.3390/rs14091973
Chicago/Turabian StyleHu, Xing, Chun Xie, Zhe Fan, Qianqian Duan, Dawei Zhang, Linhua Jiang, Xian Wei, Danfeng Hong, Guoqiang Li, Xinhua Zeng, and et al. 2022. "Hyperspectral Anomaly Detection Using Deep Learning: A Review" Remote Sensing 14, no. 9: 1973. https://doi.org/10.3390/rs14091973
APA StyleHu, X., Xie, C., Fan, Z., Duan, Q., Zhang, D., Jiang, L., Wei, X., Hong, D., Li, G., Zeng, X., Chen, W., Wu, D., & Chanussot, J. (2022). Hyperspectral Anomaly Detection Using Deep Learning: A Review. Remote Sensing, 14(9), 1973. https://doi.org/10.3390/rs14091973