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  • Event label; File format; File name; File size; Hyperspectral Imager/Profiler; HYSP; JPI-OCEANS; JPI Oceans - Ecological Aspects of Deep-Sea Mining; JPIO-MiningImpact; Remote operated vehicle; ROV; SO242/2; SO242/2_191_HYSP-1; SO242/2_191_HYSP-10; SO242/2_191_HYSP-11; SO242/2_191_HYSP-12; SO242/2_191_HYSP-13; SO242/2_191_HYSP-14; SO242/2_191_HYSP-15; SO242/2_191_HYSP-2; SO242/2_191_HYSP-3; SO242/2_191_HYSP-4; SO242/2_191_HYSP-5; SO242/2_191_HYSP-6; SO242/2_191_HYSP-7; SO242/2_191_HYSP-8; SO242/2_191_HYSP-9; SO242/2_191-1; Sonne_2; South Pacific Ocean, Peru Basin; Uniform resource locator/link to file  (1)
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    Hyperspectral imager (UHI) data files acquired on SONNE cruise SO242/2, ROV dive SO242/191-1 (2017)
    PANGAEA
    In:  Supplement to: Dumke, Ines; Nornes, Stein; Purser, Autun; Marcon, Yann; Ludvigsen, Martin; Ellefmo, Steinar L; Johnsen, Geir; Søreide, Fredrik (2018): First hyperspectral imaging survey of the deep seafloor: High-resolution mapping of manganese nodules. Remote Sensing of Environment, 209, 19-30, https://doi.org/10.1016/j.rse.2018.02.024
    Details
    Publication Date: 2023-03-03
    Description: Hyperspectral seafloor surveys using airborne or spaceborne sensors are generally limited to shallow coastal areas, due to the requirement for target illumination by sunlight. Deeper marine environments devoid of sunlight cannot be imaged by conventional hyperspectral imagers. Instead, a close-range, sunlight-independent hyperspectral survey approach is required. In this study, we present the first hyperspectral image data from the deep seafloor. The data were acquired in approximately 4200 m water depth using a new Underwater Hyperspectral Imager (UHI) mounted on a remotely operated vehicle (ROV). UHI data were recorded for 112 spectral bands between 378 nm and 805 nm, with a high spectral (4 nm) and spatial resolution (1 mm per image pixel). The study area was located in a manganese nodule field in the Peru Basin (SE Pacific), close to the DISCOL (DISturbance and reCOLonization) experimental area. To test whether underwater hyperspectral imaging can be used for detection and mapping of mineral deposits in potential deep-sea mining areas, we compared two supervised classification methods, the Support Vector Machine (SVM) and the Spectral Angle Mapper (SAM). The results show that SVM is superior to SAM and is able to accurately detect nodule surfaces. The UHI therefore represents a promising tool for high-resolution seafloor exploration and characterisation prior to resource exploitation.
    Keywords: Event label; File format; File name; File size; Hyperspectral Imager/Profiler; HYSP; JPI-OCEANS; JPI Oceans - Ecological Aspects of Deep-Sea Mining; JPIO-MiningImpact; Remote operated vehicle; ROV; SO242/2; SO242/2_191_HYSP-1; SO242/2_191_HYSP-10; SO242/2_191_HYSP-11; SO242/2_191_HYSP-12; SO242/2_191_HYSP-13; SO242/2_191_HYSP-14; SO242/2_191_HYSP-15; SO242/2_191_HYSP-2; SO242/2_191_HYSP-3; SO242/2_191_HYSP-4; SO242/2_191_HYSP-5; SO242/2_191_HYSP-6; SO242/2_191_HYSP-7; SO242/2_191_HYSP-8; SO242/2_191_HYSP-9; SO242/2_191-1; Sonne_2; South Pacific Ocean, Peru Basin; Uniform resource locator/link to file
    Type: Dataset
    Format: text/tab-separated-values, 80 data points
    Location Call Number Expected Availability
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