Evaluating and Improving NWP Forecast Models for the Future: How the Needs of Offshore Wind Energy Can Point the Way

Author:

Banta Robert M.1,Pichugina Yelena L.2,Brewer W. Alan1,James Eric P.2,Olson Joseph B.2,Benjamin Stanley G.1,Carley Jacob R.3,Bianco Laura2,Djalalova Irina V.2,Wilczak James M.1,Hardesty R. Michael2,Cline Joel4,Marquis Melinda C.1

Affiliation:

1. National Oceanic and Atmospheric Administration/Earth System Research Laboratory, Boulder, Colorado

2. Cooperative Institute for Research in Environmental Sciences, University of Colorado Boulder, and National Oceanic and Atmospheric Administration/Earth System Research Laboratory, Boulder, Colorado

3. I.M. Systems Group, Inc., and National Oceanic and Atmospheric Administration/National Weather Service/Environmental Modeling Center, College Park, Maryland

4. Office of Energy Efficiency and Renewable Energy, Department of Energy, Washington, D.C.

Abstract

AbstractTo advance the understanding of meteorological processes in offshore coastal regions, the spatial variability of wind profiles must be characterized and uncertainties (errors) in NWP model wind forecasts quantified. These gaps are especially critical for the new offshore wind energy industry, where wind profile measurements in the marine atmospheric layer spanned by wind turbine rotor blades, generally 50–200 m above mean sea level (MSL), have been largely unavailable. Here, high-quality wind profile measurements were available every 15 min from the National Oceanic and Atmospheric Administration/Earth System Research Laboratory (NOAA/ESRL)’s high-resolution Doppler lidar (HRDL) during a monthlong research cruise in the Gulf of Maine for the 2004 New England Air Quality Study. These measurements were compared with retrospective NWP model wind forecasts over the area using two NOAA forecast-modeling systems [North American Mesoscale Forecast System (NAM) and Rapid Refresh (RAP)]. HRDL profile measurements quantified model errors, including their dependence on height above sea level, diurnal cycle, and forecast lead time. Typical model wind speed errors were ∼2.5 m s−1, and vector-wind errors were ∼4 m s−1. Short-term forecast errors were larger near the surface—30% larger below 100 m than above and largest for several hours after local midnight (biased low). Longer-term, 12-h forecasts had the largest errors after local sunset (biased high). At more than 3-h lead times, predictions from finer-resolution models exhibited larger errors. Horizontal variability of winds, measured as the ship traversed the Gulf of Maine, was significant and raised questions about whether modeled fields, which appeared smooth in comparison, were capturing this variability. If not, horizontal arrays of high-quality, vertical-profiling devices will be required for wind energy resource assessment offshore. Such measurement arrays are also needed to improve NWP models.

Publisher

American Meteorological Society

Subject

Atmospheric Science

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