Underwater Radiance Distributions Measured with Miniaturized Multispectral Radiance Cameras

Antoine, David; Morel, A.; Leymarie, Édouard; Houyou, Amel; Gentili, Bernard; Victori, Stéphane; Buis, Jean-Pierre; Buis, N.; Meunier, Sylvain; Canini, Marius; Crozel, Didier; Fougnie, Bertrand; Henry, Patrice

doi:10.1175/jtech-d-11-00215.1

Cited by 23 publications

(20 citation statements)

References 45 publications

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“…Note that there are currently no agreed look-up tables for the Q-factor in turbid coastal waters, but see the simulations made by Loisel and Morel (2001) and Park and Ruddick (2005). The Q-factors measured along river transects during the Malina field campaign, using a miniaturized multispectral (406, 438, 494, 510, 560 and 628 nm) radiance camera (see Antoine et al, 2012 for measurement details), showed very limited spectral variations: maximum variations of 10 % between 406 and 628 nm, 7 % on average, at nadir. While limited to the visible spectral domain, these measurements support the use of a spectrally-flat Q-factor in our model.…”

Section: Ocean Colour Spm Quantification Algorithmmentioning

confidence: 99%

Optical characterisation of suspended particles in the Mackenzie River plume (Canadian Arctic Ocean) and implications for ocean colour remote sensing

et al. 2012

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Abstract. Climate change significantly impacts Arctic shelf regions in terms of air temperature, ultraviolet radiation, melting of sea ice, precipitation, thawing of permafrost and coastal erosion. Direct consequences have been observed on the increasing Arctic river flow and a large amount of organic carbon sequestered in soils at high latitudes since the last glacial maximum can be expected to be delivered to the Arctic Ocean during the coming decade. Monitoring the fluxes and fate of this terrigenous organic carbon is problematic in such sparsely populated regions unless remote sensing techniques can be developed and proved to be operational.The main objective of this study is to develop an ocean colour algorithm to operationally monitor dynamics of suspended particulate matter (SPM) on the Mackenzie River continental shelf (Canadian Arctic Ocean) using satellite imagery. The water optical properties are documented across the study area and related to concentrations of SPM and particulate organic carbon (POC). Robust SPM and POC : SPM proxies are identified, such as the light backscattering and attenuation coefficients, and relationships are established between these optical and biogeochemical parameters. Following a semi-analytical approach, a regional SPM quantification relationship is obtained for the inversion of the water reflectance signal into SPM concentration. This relationship is reproduced based on independent field optical measurements. It is successfully applied to a selection of MODIS satellite data which allow estimating fluxes at the river mouth and monitoring the extension and dynamics of the Mackenzie River surface plume in 2009, 2010 and 2011. Good agreement is obtained with field observations representative of the whole water column in the river delta zone where terrigenous SPM is mainly constrained (out of short periods of maximum river outflow). Most of the seaward export of SPM is observed to occur within the west side of the river mouth.Future work will require the validation of the developed SPM regional algorithm based on match-ups with field measurements, then the routine application to ocean colour satellite data in order to better estimate the fluxes and fate of SPM and POC delivered by the Mackenzie River to the Arctic Ocean.

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Section: Ocean Colour Spm Quantification Algorithmmentioning

confidence: 99%

Optical characterisation of suspended particles in the Mackenzie River plume (Canadian Arctic Ocean) and implications for ocean colour remote sensing

et al. 2012

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“…Here a novel method is introduced to determine the sea ice and snow anisotropy of a surface ranging from 1 m 2 to 80 m 2 at a hyperangular resolution. The new method relies on a state‐of‐the‐art multispectral circular fish‐eye radiance camera manufactured by CIMEL Electronique (Paris, France) and allows instantaneous radiance measurements over a hemisphere at about 1° and six different visible spectral bands, referred to as the CE600 (Antoine et al, ). In addition, reflectance anisotropy was also measured with a hyperspectral field spectroradiometer manufactured by Analytical Spectral Device, Inc. (hereafter referred to as ASD) mounted on a goniometer.…”

Section: Introductionmentioning

confidence: 99%

High Angular Resolution Measurements of the Anisotropy of Reflectance of Sea Ice and Snow

Goyens

Marty

Leymarie

et al. 2018

Earth and Space Science

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We introduce a new method to determine the anisotropy of reflectance of sea ice and snow at spatial scales from 1 m2 to 80 m2 using a multispectral circular fish‐eye radiance camera (CE600). The CE600 allows measuring radiance simultaneously in all directions of a hemisphere at a 1° angular resolution. The spectral characteristics of the reflectance and its dependency on illumination conditions obtained from the camera are compared to those obtained with a hyperspectral field spectroradiometer manufactured by Analytical Spectral Device, Inc. (ASD). Results confirm the potential of the CE600, with the suggested measurement setup and data processing, to measure commensurable sea ice and snow hemispherical‐directional reflectance factor, HDRF, values. Compared to the ASD, the reflectance anisotropy measured with the CE600 provides much higher resolution in terms of directional reflectance (N = 16,020). The hyperangular resolution allows detecting features that were overlooked using the ASD due to its limited number of measurement angles (N = 25). This data set of HDRF further documents variations in the anisotropy of the reflectance of snow and ice with the geometry of observation and illumination conditions and its spectral and spatial scale dependency. Finally, in order to reproduce the hyperangular CE600 reflectance measurements over the entire 400–900 nm spectral range, a regression‐based method is proposed to combine the ASD and CE600 measurements. Results confirm that both instruments may be used in synergy to construct a hyperangular and hyperspectral snow and ice reflectance anisotropy data set.

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“…The contribution of water molecular scattering is included in the under-light model (details can be found in Sayer et al, 2010). Recent measurements also report on the angular dependence of the ocean surface reflectance (e.g., Voss and Chapin, 2005;Antoine et al, 2013). However, it is not clear how general these results might be, so including this refinement is beyond the scope of the current study; having additional constraints on ocean surface BRDF would be an asset to multi-angle remote sensing of Earth's surface.…”

Section: Ocean Surface Modelmentioning

confidence: 99%

MISR research-aerosol-algorithm refinements for dark water retrievals

Limbacher

Kahn

2014

Atmos. Meas. Tech.

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Abstract. We explore systematically the cumulative effect of many assumptions made in the Multi-angle Imaging SpectroRadiometer (MISR) research aerosol retrieval algorithm with the aim of quantifying the main sources of uncertainty over ocean, and correcting them to the extent possible. A total of 1129 coincident, surface-based sun photometer spectral aerosol optical depth (AOD) measurements are used for validation. Based on comparisons between these data and our baseline case (similar to the MISR standard algorithm, but without the "modified linear mixing" approximation), for 558 nm AOD < 0.10, a high bias of 0.024 is reduced by about one-third when (1) ocean surface under-light is included and the assumed whitecap reflectance at 672 nm is increased, (2) physically based adjustments in particle microphysical properties and mixtures are made, (3) an adaptive pixel selection method is used, (4) spectral reflectance uncertainty is estimated from vicarious calibration, and (5) minor radiometric calibration changes are made for the 672 and 866 nm channels. Applying (6) more stringent cloud screening (setting the maximum fraction not-clear to 0.50) brings all median spectral biases to about 0.01. When all adjustments except more stringent cloud screening are applied, and a modified acceptance criterion is used, the Root-Mean-Square-Error (RMSE) decreases for all wavelengths by 8-27 % for the research algorithm relative to the baseline, and is 12-36 % lower than the RMSE for the Version 22 MISR standard algorithm (SA, with no adjustments applied). At 558 nm, 87 % of AOD data falls within the greater of 0.05 or 20 % of validation values; 62 % of the 446 nm AOD data, and > 68 % of 558, 672, and 866 nm AOD values fall within the greater of 0.03 or 10 %. For the Ångström exponent (ANG), 67 % of 1119 validation cases for AOD > 0.01 fall within 0.275 of the sun photometer values, compared to 49 % for the SA. ANG RMSE decreases by 17 % compared to the SA, and the median absolute error drops by 36 %.

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Underwater Radiance Distributions Measured with Miniaturized Multispectral Radiance Cameras

Cited by 23 publications

References 45 publications

Optical characterisation of suspended particles in the Mackenzie River plume (Canadian Arctic Ocean) and implications for ocean colour remote sensing

Optical characterisation of suspended particles in the Mackenzie River plume (Canadian Arctic Ocean) and implications for ocean colour remote sensing

High Angular Resolution Measurements of the Anisotropy of Reflectance of Sea Ice and Snow

MISR research-aerosol-algorithm refinements for dark water retrievals

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