Weather Research and Forecasting Model: Difference between revisions

[[File:Typhoon Mawar 2005 computer simulation thumbnail.gif|right|thumb|250px|WRF model output showing simulated radar reflectivity (dBZ) for [[2005 Pacific typhoon season#Typhoon Mawar (2005)|Typhoon Mawar]] at 3.3-km (2.1-mi) grid spacing. Time period is from 0000 UTC 22 August 2005 to 0000 UTC 24 August 2005.]]

The '''Weather Research and Forecasting''' ('''WRF''') model'''Model'''<ref>{{Cite web|url=https://www.mmm.ucar.edu/weather-research-and-forecasting-model| title=WRF Model site}}</ref> ({{IPAc-en|ˈ|w|ɔr|f}}) is a [[numerical weather prediction]] (NWP) system designed to serve both atmospheric research and operational forecasting needs, developed in the United States. NWP refers to the simulation and prediction of the atmosphere with a computer model, and WRF is a set of software for this. WRF features two dynamical (computational) cores (or ''solvers''), a [[data assimilation]] system, and a software architecture allowing for parallel computation and system extensibility. The model serves a wide range of meteorological applications across scales ranging from meters to thousands of kilometers.

WRF allows researchers to produce simulations reflecting either real data (observations, analyses) or idealized atmospheric conditions. WRF provides operational forecasting a flexible and robust platform, while offering advances in physics, numerics, and data assimilation contributed by the many research community developers. WRF is currently in operational use at NCEP and other forecasting centers internationally. WRF has grown to have a large worldwide community of users (over 30,000 registered users in over 150 countries), and workshops and tutorials are held each year at NCAR. WRF is used extensively for research and real-time forecasting throughout the world. It has been shown to perform well in simulating [[Convection#Atmospheric convection|Atmosphericatmospheric convection]],<ref>{{Cite journal|doi=10.1175/MWR2830.1|title=Evaluating Mesoscale NWP Models Using Kinetic Energy Spectra|year=2004|last1=Skamarock|first1=William C.|journal=Monthly Weather Review|volume=132|issue=12|pages=3019–3032|bibcode=2004MWRv..132.3019S|doi-access=free}}</ref><ref>{{Cite journal|doi=10.1175/MWR-D-15-0326.1|title=Evolution of the Diurnal Precipitation Cycle with the Passage of a Madden–Julian Oscillation Event through the Maritime Continent|year=2016|last1=Vincent|first1=Claire L.|last2=Lane|first2=Todd P.|journal=Monthly Weather Review|volume=144|issue=5|pages=1983–2005|bibcode=2016MWRv..144.1983V|doi-access=free|hdl=11343/197698|hdl-access=free}}</ref> but to be prone to producing [[squall line]]s too easily.<ref>{{Cite journal| doi=10.1002/qj.3855| title=Locally forced convection in sub‐kilometre scale simulations with the Unified Model and WRF| year=2020| last1=Jucker| first1=M.| last2=Lane| first2=T.P.| last3=Vincent| first3=C.L.| last4=Webster| first4=S.| last5=Wales| first5=S.A.| last6=Louf| first6=V.| journal=Quarterly Journal of the Royal Meteorological Society| volume=146| issue=732| pages=3450–3465| bibcode=2020QJRMS.146.3450J| doi-access=free| hdl=11343/241629| hdl-access=free}}</ref>

The WRF serves as the basis for the [[Rapid Refresh (weather prediction)|RAP and HRRR models]]: high-resolution operational forecast models run regularly at NCEP. The WRF also serves as the basis for the [[North American Mesoscale]] (NAM) model at 12km and 3km grid resolutions. <ref>{{Cite web|url=https://rapidrefresh.noaa.gov/RR.faq.html|title=Rapid Refresh Frequently Asked Questions|website=rapidrefresh.noaa.gov}}</ref><ref>{{cite web|url=https://dtcenter.org/plots/hwt/model.php|archive-url=https://web.archive.org/web/20150218185729/https://dtcenter.org/plots/hwt/model.php|title=HWT 2009 Spring Experiment Objective Verification|archive-date=2015-02-18}}</ref>