Underwater Use of a Hyperspectral Camera to Estimate Optically Active Substances in the Water Column of Freshwater Lakes

Michael Seidel,András Jung,Felix Oertel,Christopher Hutengs,Michael Vohland,Daniel Schwefel

doi:10.3390/rs12111745

Michael Seidel, András Jung + Show 4 more

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https://doi.org/10.3390/rs12111745

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Abstract

Freshwater lakes provide many important ecosystem functions and services to support biodiversity and human well-being. Proximal and remote sensing methods represent an efficient approach to derive water quality indicators such as optically active substances (OAS). Measurements of above-ground remote and in situ proximal sensors, however, are limited to observations of the uppermost water layer. We tested a hyperspectral imaging system, customized for underwater applications, with the aim to assess concentrations of chlorophyll a (CHLa) and colored dissolved organic matter (CDOM) in the water columns of four freshwater lakes with different trophic conditions in Central Germany. We established a measurement protocol that allowed consistent reflectance retrievals at multiple depths within the water column independent of ambient illumination conditions. Imaging information from the camera proved beneficial for an optimized extraction of spectral information since low signal areas in the sensor’s field of view, e.g., due to non-uniform illumination, and other interfering elements, could be removed from the measured reflectance signal for each layer. Predictive hyperspectral models, based on the 470 nm–850 nm reflectance signal, yielded estimates of both water quality parameters (R² = 0.94, RMSE = 8.9 µg L−1 for CHLa; R² = 0.75, RMSE = 0.22 m−1 for CDOM) that were more accurate than commonly applied waveband indices (R² = 0.83, RMSE = 13.2 µg L−1 for CHLa; R² = 0.66, RMSE = 0.25 m−1 for CDOM). Underwater hyperspectral imaging could thus facilitate future water monitoring efforts through the acquisition of consistent spectral reflectance measurements or derived water quality parameters along the water column, which has the potential to improve the link between above-surface proximal and remote sensing observations and in situ point-based water probe measurements for ground truthing or to resolve the vertical distribution of OAS.

Highlights

Lake ecosystems provide essential functions and services, including contributions to biodiversity, hydrologic regulation and water supply, and human well-being through their recreational benefits [1,2]
We evaluated the capabilities of a hyperspectral snapshot camera system to resolve the vertical distribution of chlorophyll a (CHLa) and colored dissolved organic matter (CDOM) in pre-defined segments in the water column
For reasons of comparison with the hyperspectral camera, we reduced the ASD spectra to a range between 470 and 850 nm

Summary

Introduction

Lake ecosystems provide essential functions and services, including contributions to biodiversity, hydrologic regulation and water supply, and human well-being through their recreational benefits [1,2]. Remote sensing in the visible and near-infrared (VNIR) range (400–1000 nm) allows for the spatio-temporal monitoring of various water quality parameters in freshwater lakes [4,5]. In the case of optically complex inland water bodies, the variety of OAS concentrations and their specific inherent optical properties is wide and independent from each other [6,9]. This complexity limits the use of simple band ratio approaches and might affect the accuracy of analytical models due to partly unknown optical properties of contributing OAS [7,10]

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