MODIS-derived green Noctiluca blooms in the upper Gulf of Thailand: Algorithm development and seasonal variation mapping

Luang-on, Jutarak; Ishizaka, Joji; Buranapratheprat, Anukul; Phaksopa, Jitraporn; Goés, Joaquim I.; Maúre, Elígio de Ráus; Siswanto, Eko; Zhu, Yuanli; Xu, Qiang; Nakornsantiphap, Phattaranakorn; Kobayashi, Hiroshi; Matsumura, Satsuki

doi:10.3389/fmars.2023.1031901

Cited by 4 publications

(1 citation statement)

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“…We believe that our forward simulations offer more consistent observing conditions compared to in situ measurement data collections, which can be affected by varying conditions and measurement protocols (Lehmann et al 2023). Moreover, the current framework has limitations in certain scenarios, such as optically shallow waters with varying bottom reflectance (Dierssen et al 2015; Qi et al 2020) and unique floating aggregations (e.g., Noctiluca; Luang‐on et al 2023; Kordubel et al 2024). Addressing these scenarios will require additional knowledge from in situ observations and radiative transfer modeling in future research.…”

Section: Discussionmentioning

confidence: 99%

Holistic optical water type classification for ocean, coastal, and inland waters

Bi,

Hieronymi

2024

Limnology & Oceanography

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Water constituents exhibit diverse optical properties across ocean, coastal, and inland waters, which alter their remote‐sensing reflectance obtained via satellites. Optical water type (OWT) classifications utilized in satellite data processing aim to mitigate optical complexity by identifying fitting ocean color algorithms tailored to each water type. This facilitates comprehension of biogeochemical cycles ranging from local to global scales. Previous OWT frameworks have focused narrowly on either oceanic or inland waters and have relied too heavily on specific data collections. We propose a novel holistic OWT framework applicable to all natural waters, based on state‐of‐the‐art bio‐geo‐optical modeling and radiative transfer simulations that encompass different phytoplankton groups. This framework employs a “knowledge‐driven” paradigm, combining domain knowledge and insights from previous studies to simulate the reflectance spectrum from water constituent concentrations and inherent optical properties. Our method extracts optical variables to represent the full spectrum of reflectance, consolidating both spectral shape and magnitude. We apply the framework utilizing diverse in situ, synthetic, and satellite data (Sentinel‐3 OLCI) and demonstrate its better classifiability than other frameworks. This framework lays the foundation for comprehensive global monitoring of natural waters.

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