Global and Local Real-Time Anomaly Detectors for Hyperspectral Remote Sensing Imagery
Abstract
:1. Introduction
2. Commonly Used Global and Local Anomaly Detectors
2.1. Global RX Detector
2.2. Local RX Detector
3. Real-Time Anomaly Detectors
3.1. Global Real-Time Detector
3.2. Local Real-Time Detector
4. Experiments
4.1. Data Set Descriptions
Sensor | AVIRIS |
---|---|
Wavelength | 400–1800 nm |
Bands | 158 |
Spectral resolution | 10 nm |
Spatial resolution | 20 m |
Image size | 200 × 200 |
Gray range | 0–10,000 |
Location | Northern Nye County, NV |
4.2. Global Real-Time Processing Experiments
4.3. Local Real-Time Processing Experiments
Measures | Alunite (A) | Buddingtonite (B) | Calcite (C) | Kaolinite (K) | Muscovite (M) |
---|---|---|---|---|---|
SAM | 0.1821 | 0.0656 | 0.0441 | 0.1923 | 0.0924 |
SID | 0.0405 | 0.0046 | 0.0025 | 0.0522 | 0.0103 |
4.4. Computational Analysis
K-RXD (seconds) | R-RXD (seconds) | CRXD (seconds) | GRTCRXD (seconds) | LRXD (seconds) | LRTCARXD (seconds) | |
---|---|---|---|---|---|---|
Scenario TI | 1.7067 | 1.1825 | 2178.97 | 24.1223 | 332.8399 | 47.8953 |
ScenarioTE | 1.4789 | 1.1045 | 1984.92 | 22.4953 | 294.2294 | 43.1142 |
AVIRIS LCVF | 1.2293 | 0.7925 | 1471.51 | 14.9151 | 183.2476 | 28.1530 |
5. Conclusions
- The proposed real-time algorithm has two main features: (1) it is a causal procedure, in the sense that the data samples used for data processing should be only those up to the data sample vector currently being processed; (2) the processing time of the algorithm is negligible, and the proposed method could meet the efficiency requirement by updating the inverse of the correlation matrix without repeated recalculation. Taking advantage of these two features, we gain the benefit of saving data storage since it only needs to store two types of information, about the previous moment and pixel the currently being processed; this is also much easier in terms of hardware implementation because it uses an update equation instead of matrix inversion calculation.
- As demonstrated in anomaly detection results for both synthetic and real hyperspectral images, real-time processing offers the significant advantage of seeing time-varying changes in background information. As time moves along, various levels of background suppression produce false alarms, thus producing a tremendous effect on visual assessment. This issue is worth pursuing and beyond the scope of this paper. It would be interesting to investigate this issue since background suppression provides users with a better understanding of what the detected anomalies really are. Specifically, some weak anomalies detected earlier may be overwhelmed by strong anomalies detected later, as the experimental results show. However, this phenomenon is very important in anomaly detection but cannot be observed using commonly used anomaly detectors, which perform one-shot operation to show the final detected anomalies.
- Despite the fact that local anomaly detection for hyperspectral imagery is not new and has been widely discussed in the literature, the concept of a causal matrix local window (CMLW) and a causal array local window (CALW) for real-time implementation is new.
- The Woodbury matrix identity has been known for a long time but is newly used to derive a recursive equation in this paper, avoiding computing reversion of covariance/correlation matrix. This will greatly shorten the processing time. Computational complexity analysis is very important for anomaly detection because some targets, especially moving targets, provoke immediate decision-making because they may show up suddenly and then disappear quickly afterwards. As a result, for this kind of detection, the processing time must be very short. This paper gives a comparative discussion of the computing time of different algorithms, showing the advantages of time-saving through the Woodbury matrix identity theory.
- The proposed real-time detection methods have the additional benefit of being portable. Other detection algorithms, such as CEM, TCIMF, etc., could also be conducted as real-time detectors using the same methodology.
Acknowledgments
Author Contributions
Conflicts of Interest
References
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Zhao, C.; Wang, Y.; Qi, B.; Wang, J. Global and Local Real-Time Anomaly Detectors for Hyperspectral Remote Sensing Imagery. Remote Sens. 2015, 7, 3966-3985. https://doi.org/10.3390/rs70403966
Zhao C, Wang Y, Qi B, Wang J. Global and Local Real-Time Anomaly Detectors for Hyperspectral Remote Sensing Imagery. Remote Sensing. 2015; 7(4):3966-3985. https://doi.org/10.3390/rs70403966
Chicago/Turabian StyleZhao, Chunhui, Yulei Wang, Bin Qi, and Jia Wang. 2015. "Global and Local Real-Time Anomaly Detectors for Hyperspectral Remote Sensing Imagery" Remote Sensing 7, no. 4: 3966-3985. https://doi.org/10.3390/rs70403966
APA StyleZhao, C., Wang, Y., Qi, B., & Wang, J. (2015). Global and Local Real-Time Anomaly Detectors for Hyperspectral Remote Sensing Imagery. Remote Sensing, 7(4), 3966-3985. https://doi.org/10.3390/rs70403966