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Optimal cyanobacterial pigment retrieval from ocean colour sensors in a highly turbid, optically complex lake
Riddick, C.A.L.; Hunter, P.D.; Dominguez-Gomez, J.A.; Martinez-Vicente, V.; Présing, M.; Horváth, H.; Kovacs, A.W.; Vörös, L.; Zsigmond, E.; Tyler, A.N. (2019). Optimal cyanobacterial pigment retrieval from ocean colour sensors in a highly turbid, optically complex lake. Remote Sens. 11(13): 1613. https://dx.doi.org/10.3390/rs11131613
In: Remote Sensing. MDPI: Basel. ISSN 2072-4292; e-ISSN 2072-4292, more
Peer reviewed article  

Available in  Authors 

Keywords
    Cyanobacteria [WoRMS]
    Fresh water
Author keywords
    cyanobacteria; phycocyanin; MERIS; Sentinel-3; remote sensing; Lake Balaton

Authors  Top 
  • Riddick, C.A.L.
  • Hunter, P.D.
  • Dominguez-Gomez, J.A.
  • Martinez-Vicente, V., more
  • Présing, M.
  • Horváth, H.
  • Kovacs, A.W.
  • Vörös, L.
  • Zsigmond, E.
  • Tyler, A.N.

Abstract
    To date, several algorithms for the retrieval of cyanobacterial phycocyanin (PC) from ocean colour sensors have been presented for inland waters, all of which claim to be robust models. To address this, we conducted a comprehensive comparison to identify the optimal algorithm for retrieval of PC concentrations in the highly optically complex waters of Lake Balaton (Hungary). MEdium Resolution Imaging Spectrometer (MERIS) top-of-atmosphere radiances were first atmospherically corrected using the Self-Contained Atmospheric Parameters Estimation for MERIS data v.B2 (SCAPE-M_B2). Overall, the Simis05 semi-analytical algorithm outperformed more complex inversion algorithms, providing accurate estimates of PC up to ±7 days from the time of satellite overpass during summer cyanobacteria blooms (RMSElog < 0.33). Same-day retrieval of PC also showed good agreement with cyanobacteria biomass (R2 > 0.66, p < 0.001). In-depth analysis of the Simis05 algorithm using in situ measurements of inherent optical properties (IOPs) revealed that the Simis05 model overestimated the phytoplankton absorption coefficient [aph(λ)] by a factor of ~2. However, these errors were compensated for by underestimation of the mass-specific chlorophyll absorption coefficient [a*chla(λ)]. This study reinforces the need for further validation of algorithms over a range of optical water types in the context of the recently launched Ocean Land Colour Instrument (OLCI) onboard Sentinel-3.

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