Estimation of Seasonal Representation of the Sea Water Temperature Profile Using Machine Learning and Its Effect on the Prediction of Underwater Acoustic Detection Performance

Seawater temperature and salinity profiles are important physical properties that represent oceanic environments and affect underwater acoustic detection prediction performance. Average ocean data can be used to predict the SONAR detection area in areas where obtaining real-time ocean data or instan...

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Bibliographic Details
Published in:Ocean science journal 2022-09, Vol.57 (3), p.528-540
Main Authors: Park, Nayoung, Kim, Young-Gyu, Kim, Kyeong Ok, Son, Su-Uk, Park, JongJin, Kim, Young Ho
Format: Article
Language:English
Subjects:
Acoustics
Aquatic Pollution
Chemical analysis
Earth and Environmental Science
Earth Sciences
Machine learning
Marine & Freshwater Sciences
Marine environment
Mixed layer
Mixed layer depth
Oceanic analysis
Oceanography
Physical properties
Profiles
Salinity
Salinity profiles
Seawater
Sonar
Sonar detection
Temperature
Temperature gradients
Temperature profile
Thermocline
Underwater
Vertical profiles
Waste Water Technology
Water analysis
Water Management
Water Pollution Control
Water temperature
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Summary:Seawater temperature and salinity profiles are important physical properties that represent oceanic environments and affect underwater acoustic detection prediction performance. Average ocean data can be used to predict the SONAR detection area in areas where obtaining real-time ocean data or instantly predicting the SONAR detection area is difficult. However, it can yield distorted results. In this study, representative temperature profiles reflecting properties of the vertical structure at various temperatures in the study area were obtained using K-means clustering, an unsupervised machine learning technique. K-means clustering was applied to the temperature profiles obtained from the three stations of the Ulleung Basin in the East Sea. In addition, the physical characteristics of the representative profiles obtained were compared, and the representativeness of the acoustic detection area obtained from the representative profiles was evaluated. In summer, when the mixed layer was thin, each cluster was classified according to the vertical temperature gradient of the thermocline. In winter, the clusters were classified according to the mixed layer and thermocline depths, rather than the vertical temperature gradient of the thermocline. For each obtained cluster, the acoustic detection area was calculated using all the profiles and displayed as a histogram. The acoustic detection area calculated from the representative profile of the cluster was generally close to the average of the acoustic detection area. Thus, K-means clustering can effectively classify temperature profiles physically and acoustically and can potentially be applied in other regions for the classification and analysis of seawater temperature and salinity profiles.
ISSN:1738-5261
2005-7172
DOI:10.1007/s12601-022-00086-8