Spatial Coherence Between Remotely Sensed Ocean Color Data and Vertical Distribution of Lidar Backscattering in Coastal Stratified Waters

Abstract

Detection of sub-surface optical layers in marine waters has important applications in fisheries management, climate modeling and decision-based systems related in military operations. Concurrent changes in the magnitude and spatial variability of remote sensing reflectance (Rrs) ratios and submerged scattering layers were investigated in coastal waters of the northern Gulf of Alaska during summer of 2002 based on high resolution and simultaneous passive (MicroSAS) and active (Fish Lidar Oceanic Experimental, FLOE) optical measurements. Principal Component Analysis revealed that the spatial variability of total lidar backscattering signal (S) between 2.1 and 20 m depth was weakly associated with changes in the inherent optical properties (IOPs) of surface waters. Also based on a 250-m footprint the vertical attenuation of S was inversely related to the IOPs (Spearman Rank Correlation up to -0.43). Low (arithmetic average and standard deviation) and high (skewness and kurtosis) moments of Rrs(443)/Rrs(490) and Rrs(508)/Rrs(555) ratios were correlated with vertical changes in total lidar backscattering signal (S) at different locations. This suggests ihe use of sub-pixel ocean color statistics to infer the spatial distribution of sub-surface scattering layers in coastal waters characterized by stratified conditions, well defined S layers (i.e., magnitude of S maximum comparable to near surface values), and relatively high vertically integrated phytoplankton pigments in the euphotic zone (chlorophyll alpha concentration > 150 mg m(-2).

Document Details

Document Type

Technical Report

Publication Date

Jan 01, 2010

Accession Number

ADA547041

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