Combining Satellite Ocean Color Imagery and Circulation Modeling to Forecast Bio-Optical Properties: Comparison of Models and Advection Schemes

Abstract

Remote sensing of ocean color provides synoptic surface ocean bio-optical properties but is limited to real-time or climatological applications. Many applications, including navy mission planning using electro-optical sensor performance models, would benefit from a forecast capability. To achieve this, we couple satellite imagery with numerical circulation models to provide short-term (24-48 hr) forecasts of bio-optical properties. These are first-order approaches; they do not account for any biogeochemical mechanistic processes (growth, grazing, sinking, resuspension), only dynamical processes (currents). Nonetheless, by comparing forecast distributions with next-day satellite imagery, we can assess errors and estimate how strongly the physical processes control the bio-optical distribution patterns. We compare optical forecast results from three Navy models and two advection approaches. The Intra-Americas Seas Nowcast/Forecast System (IASNFS), the Hybrid Coordinate Ocean Model (H YCOM), and the Northern Gulf of Mexico Nowcast/Forecast System (NGOMNFS) provide current direction and magnitude at hourly time-steps, at 6km, 4km, and 2km resolution, respectively. We apply the current vectors from these models to 1km resolution SeaWiFS-derived bio-optical properties (chlorophyll, backscattering coefficient, total and inorganic suspended particulate matter concentration) to produce advected, surface forecast images, using both a passive tracer advection scheme (Eulerian approach) and a particle trajectory/accumulation scheme (Lagrangian approach). Difference images between the next-day, satellite-derived optical fields and the model-advected fields provide a quantitative assessment of the forecast accuracy of the three models and two advection schemes, to assess the degree to which physical dynamics control the bio-optical distribution patterns. We compare different seasons (spring vs. fall) as well as different forecast periods (24 vs. 48hr).

Document Details

Document Type

Technical Report

Publication Date

Oct 01, 2008

Accession Number

ADA503936

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