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Real-Time Anomaly Detection in Underwater Gliders: Conclusion and Referencesby@oceanography
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1,318 reads

Real-Time Anomaly Detection in Underwater Gliders: Conclusion and References

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Anomaly detection algorithm is capable of detecting anomalies like remora attachment and shark hit in diverse real-world deployments. Algorithm achieves real-time estimation through a model-based framework by continuously updating estimates based on ongoing deployment feedback. Future work will enhance estimation accuracy by incorporating large amount of glider data into a n data-driven framework.
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Authors:

(1) Ruochu Yang;

(2) Chad Lembke;

(3) Fumin Zhang;

(4) Catherine Edwards.

Abstract and Intro

Anomaly Detection Algorithm

Experimental Evaluation

Conclusion and References

IV. CONCLUSION

In this paper, we apply an anomaly detection algorithm to four real glider missions supported by the Skidaway Institute of Oceanography in the University of Georgia and the University of South Florida. On one side of generality, the algorithm is capable of detecting anomalies like remora attachment and shark hit in diverse real-world deployments based on high-resolution DBD data. On the other side of realtime performance, we simulate the online detection on subsetted SBD data. It utilizes generic data of glider trajectory and heading angle to estimate glider speed and flow speed. Anomalies can be identified by comparing the estimated glider speed with the normal speed range. False alarms can be minimized by comparing the algorithm-estimated flow speed with the glider-estimated flow speed. The algorithm achieves real-time estimation through a model-based framework by continuously updating estimates based on ongoing deployment feedback. Future work will enhance estimation accuracy by incorporating large amount of glider data into a


Fig. 15: Comparison of glider-estimated and algorithmestimated W-E (u, upper) and N-S (v, lower) flow velocities for the 2023 USF-Sam deployment based on real-time SBD data

Fig. 16: Comparison of estimated glider speed (red) and normal speed range (green) for the 2023 USF-Sam deployment based on real-time SBD data.
data-driven framework. It is also worth taking into account the impact of the anomaly on the estimated flow speed, aiding in the process of determining false alarms.

REFERENCES

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Fig. 17: Ground truth for the 2021 USF-Gansett deployment.


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Fig. 18: Post-recovery evidence of shark strike on USFGansett
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Fig. 19: Comparison of the estimated (blue) and true (red) trajectory for the 2021 USF-Gansett deployment. The four green circles are the four basis functions covering the whole trajectory.

Fig. 20: CLLE (m) for the 2021 USF-Gansett deployment.


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Fig. 21: Comparison of glider-estimated and algorithmestimated W-E (u, upper) and N-S (v, lower) flow velocities for the 2021 USF-Gansett deployment.
Fig. 22: Comparison of estimated glider speed (red) and normal speed range (green) for the 2021 USF-Gansett deployment.

Fig. 23: ground truth for the 2023 USF-Stella deployment.


Fig. 24: Broken support rails of USF-Stella.


Fig. 25: Comparison of the estimated (blue) and true (red) trajectory for the 2023 USF-Stella deployment. The four green circles are the four basis functions covering the whole trajectory.
Fig. 26: CLLE (m) for the 2023 USF-Stella deployment.

Fig. 27: Comparison of glider-estimated and algorithm-estimated W-E (u, upper) and N-S (v, lower) flow velocities for the 2023 USF-Stella deployment.


Fig. 28: Comparison of estimated glider speed (red) and normal speed range (green) for the 2023 USF-Stella deployment.


This paper is available on arxiv under CC 4.0 license.