Determination of Primary Spectral Bands for Remote Sensing of Aquatic Environments
| العنوان: | Determination of Primary Spectral Bands for Remote Sensing of Aquatic Environments |
|---|---|
| المؤلفون: | Kendall L. Carder, Zhongping Lee, Robert Arnone, MingXia He |
| المصدر: | Sensors (Basel, Switzerland) Sensors, Vol 7, Iss 12, Pp 3428-3441 (2007) Sensors; Volume 7; Issue 12; Pages: 3428-3441 |
| بيانات النشر: | Molecular Diversity Preservation International (MDPI), 2007. |
| سنة النشر: | 2007 |
| مصطلحات موضوعية: | Ocean-color remote sensing, Spectrometer, Aquatic biology, spectral bands, Hyperspectral imaging, Spectral bands, Coastal Zone Color Scanner, lcsh:Chemical technology, Biochemistry, Atomic and Molecular Physics, and Optics, Spectral line, Full Research Paper, Analytical Chemistry, Wavelength, SeaWiFS, Environmental science, lcsh:TP1-1185, Electrical and Electronic Engineering, Instrumentation, Physics::Atmospheric and Oceanic Physics, Remote sensing |
| الوصف: | About 30 years ago, NASA launched the first ocean-color observing satellite: the Coastal Zone Color Scanner. CZCS had 5 bands in the visible-infrared domain with an objective to detect changes of phytoplankton (measured by concentration of chlorophyll) in the oceans. Twenty years later, for the same objective but with advanced technology, the Sea-viewing Wide Field-of-view Sensor (SeaWiFS, 7 bands), the Moderate-Resolution Imaging Spectrometer (MODIS, 8 bands), and the Medium Resolution Imaging Spectrometer (MERIS, 12 bands) were launched. The selection of the number of bands and their positions was based on experimental and theoretical results achieved before the design of these satellite sensors. Recently, Lee and Carder (2002) demonstrated that for adequate derivation of major properties (phytoplankton biomass, colored dissolved organic matter, suspended sediments, and bottom properties) in both oceanic and coastal environments from observation of water color, it is better for a sensor to have ∼15 bands in the 400 – 800 nm range. In that study, however, it did not provide detailed analyses regarding the spectral locations of the 15 bands. Here, from nearly 400 hyperspectral (∼ 3-nm resolution) measurements of remote-sensing reflectance (a measure of water color) taken in both coastal and oceanic waters covering both optically deep and optically shallow waters, first- and second-order derivatives were calculated after interpolating the measurements to 1-nm resolution. From these derivatives, the frequency of zero values for each wavelength was accounted for, and the distribution spectrum of such frequencies was obtained. Furthermore, the wavelengths that have the highest appearance of zeros were identified. Because these spectral locations indicate extrema (a local maximum or minimum) of the reflectance spectrum or inflections of the spectral curvature, placing the bands of a sensor at these wavelengths maximizes the potential of capturing (and then restoring) the spectral curve, and thus maximizes the potential of accurately deriving properties of the water column and/or bottom of various aquatic environments with a multi-band sensor. |
| وصف الملف: | application/pdf |
| اللغة: | English |
| تدمد: | 1424-8220 |
| URL الوصول: | https://explore.openaire.eu/search/publication?articleId=doi_dedup___::cc99a6c1ed69b59afe228212f869e1f8 http://europepmc.org/articles/PMC3841904 |
| Rights: | OPEN |
| رقم الانضمام: | edsair.doi.dedup.....cc99a6c1ed69b59afe228212f869e1f8 |
| قاعدة البيانات: | OpenAIRE |
| تدمد: | 14248220 |
|---|