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    Journals >Laser & Optoelectronics Progress >Volume 55 >Issue 1 >Page 12802 > Article
    • Laser & Optoelectronics Progress
    • Vol. 55, Issue 1, 12802 (2018)
    Propagation Characteristics of Internal Waves in the Strait of Gibraltar Based on MODIS Remote Sensing Images
    Shi Lu, Wang Jing*, and Mei Yuan
    Author Affiliations
  • Department of Physics, College of Information Science and Engineering, Ocean University of China,Qingdao, Shandong 266100, China
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    DOI: 10.3788/LOP55.012802 Cite this Article Set citation alerts
    Shi Lu, Wang Jing, Mei Yuan. Propagation Characteristics of Internal Waves in the Strait of Gibraltar Based on MODIS Remote Sensing Images[J]. Laser & Optoelectronics Progress, 2018, 55(1): 12802 Copy Citation Text show less
    Bathymetry of the Strait of Gibraltar. The triangle represents the position of Camarinal sill
    Fig. 1. Bathymetry of the Strait of Gibraltar. The triangle represents the position of Camarinal sill
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    Internal waves of MODIS image in the Strait of Gibraltar in 2016
    Fig. 2. Internal waves of MODIS image in the Strait of Gibraltar in 2016
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    Spatial distribution of internal waves in the Strait of Gibraltar (2014—2016)
    Fig. 3. Spatial distribution of internal waves in the Strait of Gibraltar (2014—2016)
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    Internal wave packets in different locations in the Strait of Gibraltar in 2014
    Fig. 4. Internal wave packets in different locations in the Strait of Gibraltar in 2014
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    Temporal distribution of internal waves (2014-2016)
    Fig. 5. Temporal distribution of internal waves (2014-2016)
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    Frequency distribution of internal waves
    Fig. 6. Frequency distribution of internal waves
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    Sea surface elevation for generation and propagation of internal waves. (a) t=0 h; (b) t=14.88 h; (c) t=19.84 h; (d) t=24.8 h; (e) t=29.76 h; (f) t=34.72 h
    Fig. 7. Sea surface elevation for generation and propagation of internal waves. (a) t=0 h; (b) t=14.88 h; (c) t=19.84 h; (d) t=24.8 h; (e) t=29.76 h; (f) t=34.72 h
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    Cross-section of isotherm for generation and propagation of internal waves.(a) t=17.36 h; (b) t=19.84 h; (c) t=22.32 h; (d) t=24.80 h; (e) t=27.28 h; (f) t=29.76 h
    Fig. 8. Cross-section of isotherm for generation and propagation of internal waves.(a) t=17.36 h; (b) t=19.84 h; (c) t=22.32 h; (d) t=24.80 h; (e) t=27.28 h; (f) t=29.76 h
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    Shi Lu, Wang Jing, Mei Yuan. Propagation Characteristics of Internal Waves in the Strait of Gibraltar Based on MODIS Remote Sensing Images[J]. Laser & Optoelectronics Progress, 2018, 55(1): 12802
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    Paper Information
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