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A model for the diffuse attenuation coefficient of downwelling irradiance (2005)

Lee, Zhong-Ping

American Geophysical Union

In: Journal of Geophysical Research. 2005; 110(C2): C02016. Published 2005 Jan 01. doi: 10.1029/2004jc002275.

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Publication Date: 2005-01-01

Print ISSN: 0148-0227

Electronic ISSN: 2156-2202

Topics: Geosciences

Published by American Geophysical Union

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Diffuse attenuation coefficient of downwelling irradiance: An evaluation of remote sensing methods (2005)

Lee, Zhong-Ping

American Geophysical Union

In: Journal of Geophysical Research. 2005; 110(C2): C02017. Published 2005 Jan 01. doi: 10.1029/2004jc002573.

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Publication Date: 2005-01-01

Print ISSN: 0148-0227

Electronic ISSN: 2156-2202

Topics: Geosciences

Published by American Geophysical Union

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Properties of the Water Column and Bottom Derived from AVIRIS Data (2001)

Carder, Kendall L. ; Peacock, Thomas G. ; Chen, F. Robert ; [et al.]

In: Other Sources

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Publication Date: 2019-07-18

Description: Using AVIRIS data as an example, we show in this study that the optical properties of the water column and bottom of a large, shallow area can be adequately retrieved using a model-driven optimization technique. The simultaneously derived properties include bottom depth, bottom albedo, and water absorption and backscattering coefficients, which in turn could be used to derive concentrations of chlorophyll, dissolved organic matter, and suspended sediments. The derived bottom depths were compared with a bathymetry chart and a boat survey and were found to agree very well. Also, the derived bottom-albedo image shows clear spatial patterns, with end members consistent with sand and seagrass. The image of absorption and backscattering coefficients indicates that the water is quite horizontally mixed. These results suggest that the model and approach used work very well for the retrieval of sub-surface properties of shallow-water environments even for rather turbid environments like Tampa Bay, Florida.

Keywords: Oceanography

Type: Semi-Annual Report for July - December, 2001; 3

Format: text

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A Multi-Band Analytical Algorithm for Deriving Absorption and Backscattering Coefficients from Remote-Sensing Reflectance of Optically Deep Waters (2001)

Carder, Kendall L. ; Lee, Zhong-Ping

In: Other Sources

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Publication Date: 2019-07-18

Description: A multi-band analytical (MBA) algorithm is developed to retrieve absorption and backscattering coefficients for optically deep waters, which can be applied to data from past and current satellite sensors, as well as data from hyperspectral sensors. This MBA algorithm applies a remote-sensing reflectance model derived from the Radiative Transfer Equation, and values of absorption and backscattering coefficients are analytically calculated from values of remote-sensing reflectance. There are only limited empirical relationships involved in the algorithm, which implies that this MBA algorithm could be applied to a wide dynamic range of waters. Applying the algorithm to a simulated non-"Case 1" data set, which has no relation to the development of the algorithm, the percentage error for the total absorption coefficient at 440 nm a (sub 440) is approximately 12% for a range of 0.012 - 2.1 per meter (approximately 6% for a (sub 440) less than approximately 0.3 per meter), while a traditional band-ratio approach returns a percentage error of approximately 30%. Applying it to a field data set ranging from 0.025 to 2.0 per meter, the result for a (sub 440) is very close to that using a full spectrum optimization technique (9.6% difference). Compared to the optimization approach, the MBA algorithm cuts the computation time dramatically with only a small sacrifice in accuracy, making it suitable for processing large data sets such as satellite images. Significant improvements over empirical algorithms have also been achieved in retrieving the optical properties of optically deep waters.

Keywords: Optics

Type: Semi-Annual Report for July - December, 2001; 5

Format: text

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Remote-Sensing Reflectance and Inherent Optical Properties for Optically Deep Waters: A Revisit (2001)

Du, Ke-Ping ; Carder, Kendall L. ; Lee, Zhong-Ping

In: Other Sources

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Publication Date: 2019-07-18

Description: Remote-sensing reflectance (r(rs)) is defined as the ratio of upwelling radiance to downwelling irradiance. Relationships between remote-sensing reflectance and inherent optical properties serve as the basis for ocean-color modeling, as well as for spectral deduction of oceanic constituents through analytical/semi-analytical models of ocean color. A decade ago, a simple and concise formula based on Monte Carlo simulations was developed by relating rrs to a property u, the ratio of backscattering (b(b)) to the sum of absorption (a) and backscattering (u = b(b)/(a+b(b))). This relationship generally ignored the shape differences in phase functions between molecular scattering and particle scattering. In this study, the relationship is updated with separate parameters for molecular and particle scattering, based on the Radiative Transfer Equation through use of Hydrolight numerical solutions. The new approach fits r(rs) better than an earlier traditional formula, for both clear and turbid waters.

Keywords: Optics

Type: Semi-Annual Report for July - December, 2001; 5

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6

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Diffuse Attenuation Coefficient of Downwelling Irradiance: An Evaluation of Remote Sensing Methods (2005)

Lee, Zhong-Ping ; Stramski, Dariusz ; Carder, Kendall L. ; [et al.]

In: Other Sources

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Publication Date: 2019-08-15

Description: The propagation of downwelling irradiance at wavelength lambda from surface to a depth (z) in the ocean is governed by the diffuse attenuation coefficient, K(sup -)(sub d)(lambda). There are two standard methods for the derivation of K(sup -)(sub d)(lambda) in remote sensing, which both are based on empirical relationships involving the blue-to-green ratio of ocean color. Recently, a semianalytical method to derive K(sup -)(sub d)(lambda) from reflectance has also been developed. In this study, using K(sup -)(sub d)(490) and K(sup -)(sub d)(443) as examples, we compare the K(sup -)(sub d)(lambda) values derived from the three methods using data collected in three different regions that cover oceanic and coastal waters, with K(sup -)(sub d)(490) ranging from approximately 0.04 to 4.0 per meter. The derived values are compared with the data calculated from in situ measurements of the vertical profiles of downwelling irradiance. The comparisons show that the two standard methods produced satisfactory estimates of K(sup -)(sub d)(lambda) in oceanic waters where attenuation is relatively low but resulted in significant errors in coastal waters. The newly developed semianalytical method appears to have no such limitation as it performed well for both oceanic and coastal waters. For all data in this study the average of absolute percentage difference between the in situ measured and the semianalytically derived K(sup -)(sub d) is approximately 14% for lambda = 490 nm and approximately 11% for lambda = 443 nm.

Keywords: Earth Resources and Remote Sensing

Type: Journal of Geophysical Research (ISSN 0148-0227); 110

Format: text

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