WRF-ARW Basics

1. WRF-ARW Basics • Fundamentals of Numerical Weather Prediction • Real vs. artificial atmosphere • Map projections • Horizontal grid staggering • Vertical coordinate systems • Definitions & Acronyms • Flavors of WRF • ARW core • NMM core • Other Numerical Weather Prediction Models • MM5 • ARPS • Global Icosahedral • WRF Model Governing Equations • Vertical coordinate and grid discretization • Time integration • Microphysics • Current Defects of WRF

2. Real vs. Artificial Atmosphere True analytical solutions are unknown! Numerical models are discrete approximations of a continuous fluid.

3. Map Projections Example of a regional high resolution grid (projection of a spherical surface onto a 2D plane) nested within a global (lat,lon) grid with spherical coordinates x = r cos  y = r  Differences in map projections require caution when dealing with flow of information across grid boundaries. WRF offers polar stereographic, Lambert conformal, Mercator and rotated Lat-Lon map projections.

4. Arakawa “A” Grid • Unstaggered grid - all variables defined everywhere. • Poor performance, first grid geometry employed in NWP models. • Noisy - large errors, short waves propagate energy in wrong direction, additional smoothing required. • Poorest at geostrophic adjustment - wave energy trapped, heights remain too high. • Can use a 2x larger time step than staggered grids.

5. Arakawa “B” Grid • Staggered, velocity at corners. • Preferred at coarse resolution. • Superior for poorly resolved inertia-gravity waves. • Good for geostrophy, Rossby waves: collocation of velocity points. • Bad for gravity waves: computational checkerboard mode. • Used by MM5 model.

6. Arakawa “C” Grid • Staggered, mass at center, normal velocity, fluxes at grid cell faces, vorticity at corners. • Preferred at fine resolution. • Superior for gravity waves. • Good for well resolved inertia-gravity waves. • Simulates Kelvin waves (shoulder on boundary) well. • Bad for poorly resolved waves: Rossby waves (computational checkerboard mode) and inertia-gravity waves due to averaging the Coriolis force. • Used by WRF-ARW, ARPS, CMAQ models.

7. Arakawa “D” Grid • Staggered, mass at center, tangential velocity along grid faces. • Poorest performance, worst dispersion properties, rarely used. • Noisy - large errors, short waves propagate energy in wrong direction.

8. Arakawa “E” Grid • Semi-staggered grid. • Equivalent to superposition of 2 C-grids, then rotated 45 degrees. • Center set to translated (lat,lon) = (0,0) to prevent distortion near edges, poles. • Developed for Eta step-mountain coordinate to enhance blocking, overcome PGF errors caused by sigma coordinates. • Controls the cascade of energy toward smaller scales. • Used by WRF-NMM and Eta models.

12. Definitions & Acronyms • WRF: Weather Research & Forecasting numerical weather prediction model • ARW: Advanced Research WRF [nee Eulerian Model (EM)] core • NMM: Nonhydrostatic Mesoscale Model core • WPS: WRF Preprocessing System (3 components) - prepares real atmospheric data for input to WRF • WRF-VAR: Variational 3D/4D data assimilation system (not used for this class) • IDV: Integrated Data Viewer - Java application for interactive visualization of WRF model output

13. Flavors of WRF (ARW) • ARW solver (research - NCAR, Boulder, Colorado) • Fully compressible, nonhydrostatic equations with hydrostatic option • Arakawa-C horizontal grid staggering • Mass-based terrain following vertical coordinate • Vertical grid spacing can vary with height • Top is a constant pressure surface • Scalar-conserving flux form for prognostic model variables • 2nd to 6th-order advection options in horizontal &vertical • One-way, two-way and movable nest options • Runge-Kutta 2nd & 3rd-order time integration options • Time-splitting • Large time step for advection • Small time step for acoustic and internal gravity waves • Small step horizontally explicit, vertically implicit • Divergence damping for suppressing sound waves • Full physics options for land surface, PBL, radiation, microphysics and cumulus parameterization • WRF-chem under development: http://ruc.fsl.noaa.gov/wrf/WG11/

14. Flavors of WRF (NMM) • NMM solver (operational - NCEP, Camp Springs, Maryland) • Fully compressible, nonhydrostatic equations with reduced hydrostatic option • Arakawa-E horizontal grid staggering, rotated latitude-longitude • Hybrid sigma-pressure vertical coordinate • Conservative, positive definite, flux-corrected scheme used for horizontal and vertical advection of TKE and water species • 2nd-order spatial that conserves a number of 1st-order and quadratic quantities, including energy and enstrophy • One-way, two-way and movable nesting options • Time-integration schemes: forward-backward for horizontally propagating fast waves, implicit for vertically propagating sound waves, Adams-Bashforth for horizontal advection and Coriolis force, and Crank-Nicholson for vertical advection • Divergence damping & E subgrid coupling for suppressing sound waves • Full physics options for land surface, PBL, radiation, microphysics (only Ferrier scheme) and cumulus parameterization • Note: Many ARW core options are not yet implemented! Nesting still under development • NMM core will be used for HWRF (hurricane version of WRF), operational in summer of 2007

15. Other NWP Models (MM5) • MM5 (research - PSU/NCAR, Boulder, Colorado) • Progenitor of WRF-ARW, mature NWP model with extensive configuration options • Support terminated, no future enhancements by NCAR’s MMM division • Nonhydrostatic and hydrostatic frameworks • Arakawa-B horizontal grid staggering • Terrain following sigma vertical coordinate • Unsophisticated advective transport schemes cause dispersion, dissipation, poor mass conservation, lack of shape preservation • Outdated Leapfrog time integration scheme • One-way and two-way (including movable) nesting options • 4-dimensional data assimilation via nudging (Newtonian relaxation), 3D-VAR, and adjoint model • Full physics options for land surface, PBL, radiation, microphysics and cumulus parameterization

16. Other NWP Models (ARPS) • ARPS (research - CAPS/OU, Norman, Oklahoma) • Advanced Regional Prediction System • Sophisticated NWP model with capabilities similar to WRF • Primarily used for tornado simulations at ultra-high (25 meter) resolutions and assimilation of experimental radar data at mesoscale • Elegant, source code, easy to read/understand/modify, ideal for research projects, very helpful scientists at CAPS • Arakawa-C horizontal grid staggering • Currently lacks full mass conservation and Runge-Kutta time integration scheme • ARPS Data Assimilation System (ADAS) under active development/enhancement (MPI version soon), faster & more flexible than WRF-SI, employed in LEAD NSF cyber-infrastructure project • wrf2arps and arps2wrf data set conversion programs available • http://www.caps.ou.edu/ARPS/arpsdownload.html

17. Global Icosahedral Model

18. WRF Model Governing Equations(Eulerian Flux Form) Momentum: ∂U/∂t + (∇ · Vu) − ∂(pφη)/∂x + ∂(pφx)/∂η = FU ∂V/∂t + (∇ · Vv) − ∂(pφη)/∂y + ∂(pφy)/∂η = FV ∂W/∂t + (∇ · Vw) − g(∂p/∂η − μ) = FW Potential Temperature: Diagnostic Hydrostatic (inverse density a): ∂Θ/∂t + (∇ · Vθ) = FΘ ∂φ/∂η = -μ Continuity: where: μ = column mass V = μv = (U,V,W) Ω = μ d(η)/dt Θ = μθ ∂μ/∂t + (∇ · V) = 0 Geopotential Height: ∂φ/∂t + μ−1[(V · ∇φ) − gW] = 0

19. WRF Vertical Coordinate h

20. Vertical Grid Discretization

21. Runge-Kutta Time Integration Φ∗ = Φt + t/3 R(Φt ) Φ∗∗ = Φt + t/2 R(Φ∗) Φt+t = Φt + t R(Φ∗∗) “2.5” Order Scheme Linear: 3rd order Non-linear: 2nd order Square Wave Advection Tests:

22. Runge-Kutta Time Step Constraint • RK3 is limited by the advective Courant number (ut/x) and the user’s choice of advection schemes (2nd through 6th order) • The maximum stable Courant numbers for advection in the RK3 scheme are almost double those in the leapfrog time-integration scheme Maximum Courant number for 1D advection in RK3

23. Time Step Configuration For 3 spatial directions, the maximum advective time step should satisfy: tmax < C x √3 umax Assuming a 10 km horizontal grid with a maximum velocity of 100 m/s, 5th-order spatial differencing and a Runge-Kutta 3rd-order time integration scheme (Courant number = 1.42): tmax < 1.42 * 10,000 1.732 * 100 < 82 seconds Use 25% less and round down, so tmax= .75 * 82 = 60 seconds. Rule of thumb: For MM5 tmax = 3 x For WRF-ARW tmax = 6 x

24. Acoustic Time Step Configuration For the forward-backward scheme used in the WRF-ARW’s 2D explicit acoustic time integration scheme, the maximum acoustic time step should satisfy: tmax < x √2 cs Assuming a 10 km horizontal grid and a sound speed of 300 m/s: tmax < 10,000 1.414 * 300 < 23.5 seconds In WRF-ARW, the ratio of the advective/acoustic time steps should be an even integer, so round down to tmax= 15 seconds. The number of sound time steps per advective time steps is what is specified in the WRF namelist input file as variable time_step_sound, which in this case would be 60 / 15 = 4.

25. Microphysics • Includes explicitly resolved water vapor, cloud and precipitation processes • Model accommodates any number of mixing-ratio variables • Four-dimensional arrays with 3 spatial indices and one species index • Memory (size of 4th dimension) is allocated depending on the scheme • Carried out at the end of the time-step as an adjustment process, does not provide tendencies • Rationale: condensation adjustment should be at the end of the time step to guarantee that the final saturation balance is accurate for the updated temperature and moisture • Latent heating forcing for potential temperature during dynamical sub-steps (saving the microphysical heating as an approximation for the next time step) • Sedimentation process is accounted for, a smaller time step is allowed to calculate vertical flux of precipitation to prevent instability • Saturation adjustment is also included

26. WRF Microphysics Options • Mixed-phase processes are those that result from the interaction of ice and water particles (e.g. riming that produces graupel or hail) • For grid sizes ≤ 10 km, where updrafts may be resolved, mixed-phase schemes should be used, particularly in convective or icing situations • For coarser grids the added expense of these schemes is not worth it because riming is not likely to be resolved

27. WRF Planetary Boundary Layer Options • All PBL schemes are 1D, assume a clear separation between subgrid and resolved eddies. Not valid for grid sizes below a few hundred meters, so must use a full 3D local sub-grid turbulence scheme instead. WRF provides a prognostic TKE equation with 1.5 order turbulence closure for this. • Medium Range Forecast Model (MRF) PBL • Counter-gradient flux for heat and moisture in unstable conditions • Enhanced vertical flux coefficients in PBL • PBL height is defined using a critical bulk Richardson number = .5 • Yonsei University (YSU) PBL • Uses counter-gradient terms to represent fluxes due to non-local gradients • Explicit treatment of entrainment layer at PBL top, entrainment is proportional to the surface buoyancy flux (supported by studies using large-eddy models) • PBL height is defined using a critical bulk Richardson number = 0, so it is only dependent on the buoyancy profile. This lowers the PBL top compared with MRF. • Mellor-Yamada-Janjic (MYJ) PBL • 2.5 order turbulence closure through a full range of atmospheric turbulent regimes • Upper limit imposed on master length scale, which depends on TKE, buoyancy and shear • In the unstable range, upper limit derived from requirement that TKE production be non-singular in the case of growing turbulence • In the stable range, upper limit derived from requirement that the ratio of variance of vertical velocity deviation and TKE cannot be smaller than in the vanishing turbulence regime • TKE production/dissipation differential equation is solved iteratively, with recently improved empirical constants.

28. Current Defects of WRF • Serious deficiencies in PBL parameterizations and land surface models produce biases/errors in the predicted surface and 2-meter temperatures, and PBL height. WRF cannot maintain shallow stable layers. • 3D/4D Variational data assimilation and Ensemble Kalman Filtering (EnKF) still under development, EnKF available to community from NCAR as part of the Data Assimilation Research Testbed (DART). • Not clear yet what to do in “convective no-man’s land” – convective parameterizations valid only at horizontal scales > 10 km, but needed to trigger convection at 5-10 km scales. • Multi-species microphysics schemes with more accurate particle size distributions and multiple moments should be developed to rectify errors in the prediction of convective cells. • Heat and momentum exchange coefficients need to be improved for high-wind conditions in order to forecast hurricane intensity. Wind wave and sea spray coupling should also be implemented. Movable, vortex-following 2-way interactive nested grid capability has recently been incorporated into the WRF framework. • Upper atmospheric processes (gravity wave drag and stratospheric physics) need to be improved for coupling with global models.

29. Technical Description of WRF-ARW For more information on the technical details of the WRF model: http://www.mmm.ucar.edu/wrf/users/docs/arw_v2.pdf