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2012-07-04
1
Progress on FIM development toward membership in the North
American Ensemble Forecast System
John M. Brown Stan BenjaminRainer Bleck Susan SahmShan Sun Jian-Wen BaoTom Henderson James RosinskiTanya Smirnova Brian Jamison
http://fim.noaa.gov
NOAA-Earth System Research LabBoulder CO
Paper 1c2.2 CMOS 2012 Congress / AMS 21st NWP and 25th WAF Conferences 29 May – 1 Jun 2012
X-section location
Flow-following-finite-volume
Icosahedral Model FIM
Temp at lowest level
Original concept and early work on FIM was by Sandy MacDonald and Jin Lee, ESRL
2012-07-04
2
FIM numerical model•Horizontal grid
• Icosahedral, Arakawa A grid – testing 60km/30km/15km•Vertical grid
• Staggered Lorenz grid, ptop = 0.5 hPa, θtop ~2200K• Generalized vertical coordinate• Generalized vertical coordinate
• Hybrid θ-σ option (64L, 38L, 21L options currently)• Hybrid σ-p option (64L, identical to GFS)
•Numerics• Adams-Bashforth 3rd order time differencing• Flux-corrected transport
•PhysicsPhysics• GFS physics suite (May 2011 version, work underway on
Q3FY12 version)•Coupled model extensions
• Chem – WRF-chem/GOCART (Georg Grell)• Ocean – icosahedral HYCOM (Shan Sun 1030 Friday)
• Finite-volume Integrations on Local Coordinate
• Efficient Indirect Addressing Scheme on Irregular Grid
Novel features of FIM:
Lee and MacDonald (MWR, 2009): A Finite-Volume Icosahedral Shallow Water Model on Local Coordinate.
Efficient Indirect Addressing Scheme on Irregular GridMacDonald, Middlecoff, Henderson, and Lee (2010, IJHPC) : MacDonald, Middlecoff, Henderson, and Lee (2010, IJHPC) :
A General Method for Modeling on Irregular Grids.A General Method for Modeling on Irregular Grids.• FIM: Hybrid σ-θ Coordinate
- Bleck, Benjamin, Lee and MacDonald (2010, MWR): On the Use of an Arbitrary Lagrangian-Eulerian Vertical Coordinate in Global Atmospheric Modeling.
• Conservative and Monotonic 3rd-ord Adams-Bashforth w/ FCT Scheme
NOAA Earth System Research Laboratory ‐ Boulder, Colorado Page 4
Conservative and Monotonic 3 ord Adams Bashforth w/ FCT Scheme-- Lee, Bleck, and MacDonald (2010, JCP): A Multistep FluxLee, Bleck, and MacDonald (2010, JCP): A Multistep Flux--Corrected Corrected Transport SchemeTransport Scheme
• Grid Optimization for Efficiency and Accuracy- Wang and Lee (2011, SIAM): Geometric Properties of Icosahedral-Hexagonal Grid
on Sphere.
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Sadourny, Arakawa, Mintz, MWR (1968)
Bisection: N=(2**m)*10 + 2 Construction of an ( )“m” is any integer ratio between arc A-B (~8000 km) and target resolution. e.g., for dx~20 km, then m=8000/20=400N=(400**2)*10+2~1.6 million points.FIM – Ning Wang (ESRL) Can use arbitrary sequence of bisections and trisections
icosahedral grid high granularitypossible with icosahedral model
The 2-D operator applied to the straight lines, rather than the 3-D operator along the curved lines, e.g.,
Stokes’ theorem:
ikl ,
ikn ,
BB
O
C
E
A
Local stereographic projection for each icosahedral grid volume for local geometry
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K
uK
t
Fvp
sEM
ufv
Fp
u
s
ps
xx
EMvfu
FIM governing equations and solution procedure
hst
hst
vt
Fs
ps
ss
pV
s
p
s
ps
ss
pV
s
p
Fps
syy
ufv
0
qhst
Fqs
ps
sq
s
pV
s
pq
Tp
CMp
CR
p
pp
CM
;
/
0;
FIM design – vertical coordinateHybrid (sigma/ isentropic) vertical coordinate Improved transport by reducing numerical dispersion from vertical cross-coordinate transport, improved stratospheric/tropospheric exchange.
• Used in NCEP Rapid Update Cycle (RUC) model
• Used in HYCOM ocean model
Installed as generalized “s”Installed as generalized svertical coordinate- can be replaced with GFS sigma-p or other coordinates.
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Staggering of variables in layer or stacked shallow-watermodels: Used in FIM
)/(, spsp
tracersotherqvu
)/(, spsp
)/(
tracersotherqvu ,,,,
tracersotherqvu ,,,,
)/(, spsp
)/(, spsp
tracersotherqvu ,,,,
FIM vertical coord hybrid σ-θ-σ option
•2 σ layers at top
•θv reference values for all levels
•σ layers at surface set at max=15 hPa
θ-σ
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ut f v M EK
x
x s p
s
u
p Fu
vt f u M EK
y
y s p
s
v
p Fv
p
s
s
Vh
p
s
ss p
s
0
Continuity equation in generalized (“s”) coordinates
s t s s s
p
s
t
s Vh
p
s
ss p
s
F
qp
s
t
s Vh
p
s
q
ss p
s
q
Fq
differentialVertical
motion
of
s surfaces
vertically
integrated
horizontal
mass flux
divergence
differential
mass flux
through
s surface
0
(~zero in fixedgrids)
(~zero in material coord.)
(known)
Initial Physics in FIMGFS physics
• Immediate goal for FIM is contributing dynamical-core diversity to NCEP Global Ensemble Forecast System
• Use of current GFS physics (Fanglin Yang’s talk 1B1.2, previous session) allows evaluation of differences between GFS and FIM dynamical cores.
Application of GFS physics to FIM
• No changes needed to physics for hybrid θ-σ applicationNo changes needed to physics for hybrid θ σ application with one exception: mod to avoid negative mass flux in deep/shallow cu, no change to GFS performance
• Applied every 180s (multiple explicit time-steps in FIM)
Current retrospective experiments with Grell-3D replacing GFS deep/shallow cumulus
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Key Recent FIM Changes April 2011
Fix to FCT numerics (error in high-order fluxes)( g )
Nov 2011
Upgrade from GFS 2010 physics to May-2011 GFS physics
Addition of icosahedral momentum diffusion (upgraded to 4th order April 2012)(upgraded to 4th order April 2012)
Currently working on upgrade to May 2012 GFS physics (major code upgrade; only minor changes to actual physics)
Track Error 2011 Atlantic/e Pacific TropicalTrack Error -2011 Atlantic/e.Pacific Tropical Cyclones• GFS oper• FIM30km real-time (EnKF IC)• FIM30km retro (hybrid IC)• FIM15km retro (hybrid IC)
2012-07-04
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500hPa Height Anomaly Correlation20o – 80o North Latitude, 00UTC only
N = 88Avg s.d.
FIM 87.72 5.05
15
FIM 87.72 5.05GFS 87.51 5.12
72h forecasts vs. raobsN. Hemisphere 20-80N
FIM better
GFS better FIM
betterGFS better
pFIM vs. GFS
(FIM lower rms errors for V, T, RH at all levels, similar results at 24h,48h)
FIM better
GFS better
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Summary• Overall FIM performance roughly equal to
GFS using GFS initial conditions• FIM forecasts often similar to GFS at 5
days, but sometimes quite different.• FIM and GFS “dropouts” often don’t
occur at same initial time• Significant improvement in FIM from 2011
to 2012 (hurricane track errors reduced byto 2012 (hurricane track errors reduced by 20%)
• Best FIM performance for wind, RH, temp• Less so for heights
NOAA/ESRL/GSD Assimilation and Modeling Branchpresentations on regional and global NWP
Tue 14:15 Global model (FIM) development (John Brown)
Tue 15:15 Boundary-layer wind simulation in low-level jets (Joe Olson)
Tue 17:30 Gridpoint Statistical Interpolation for Rapid Refresh (Ming Hu)Tue 17:30 Gridpoint Statistical Interpolation for Rapid Refresh (Ming Hu)
Wed 16:30 Storm-scale radar-data assimilation (David Dowell)
Wed 17:00 High-Resolution Rapid Refresh climatology (Eric James)
Wed 17:15 GSI cloud analysis and rawinsonde DA (Patrick Hofmann)
Thu 10:45 Rapid Refresh implementation at NCEP (John Brown)
Thu 11:00 High-Resolution Rapid Refresh overview (Curtis Alexander)
Thu 17:30 NWP guidance for a high-impact snowstorm (Ed Szoke)
Fri 10:30 Spatial discretization for global models (Shan Sun)
Fri 17:00 Snow and ice enhancements for RUC LSM (Tanya Smirnova)
2012-07-04
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Brief summary of GFS Physics
Radiation: Rapid Radiative Transfer Model for both long and short wave
Surface processes:Surface processes: Noah LSM over land surface fluxes using variable drag coefficient over sea simple sea-ice model
PBL: Han and Pan (NCEP Office Note #464) based on Troen and Mahrt, extra vertical mixing at Sc cloud top if entrainment instability criterion met
Shallow and deep convection: Han and Pan (NCEP Office Note #464) mass flux scheme
Explicit condensate allowed, Zhao and Carr (19xx, MWR) (including simple ice processes)