two consolidation projects:
DESCRIPTION
Two Consolidation Projects:. Towards an International MME: CFS+EUROSIP(UKMO,ECMWF,METF) 11 slides Towards a National MME: CFS and GFDL 18 slides. Does the NCEP CFS add to the skill of the European DEMETER-3 to produce a viable International Multi Model Ensemble (IMME) ?. - PowerPoint PPT PresentationTRANSCRIPT
Two Consolidation Projects:
• Towards an International MME: CFS+EUROSIP(UKMO,ECMWF,METF) 11
slides
• Towards a National MME: CFS and GFDL 18
slides
Does the NCEP CFS add to the skill of
the European DEMETER-3 to produce a viable
International Multi Model Ensemble (IMME) ?
Huug van den Dool
Climate Prediction Center, NCEP/NWS/NOAA
Suranjana Saha and Åke Johansson
Environmental Modeling Center, NCEP/NWS/NOAA
August 2007
DATA and DEFINITIONS USED• DEMETER-3 (DEM3) = ECMWF + METFR + UKMO
• CFS
• IMME = DEM3 + CFS
• 1981 – 2001
• 4 Initial condition months : Feb, May, Aug and Nov
• Leads 1-5
• Monthly means
DATA/Definitions USED (cont)
• Deterministic : Anomaly Correlation
• Probabilistic : Brier Score (BS) and Rank Probability Score (RPS)
• Ensemble Mean and PDF
• T2m and Prate
• Europe and United States
“ NO (fancy) consolidation, equal weights, NO Cross-validation”
DATA/Definitions USED (cont)
Verification Data :
• T2m : CPC Monthly Analysis of the CAMS + Global Historical Climate Network (Fan and Van den Dool 2007)
• Prate : CMAP (Xie-Arkin 1997)
Number of times IMME improves upon DEM-3 :
out of 20 cases (4 IC’s x 5 leads):
Region EUROPE EUROPE USA USA
Variable T2m Prate T2m Prate
AnomalyCorrelation
9 14 14 14
Brier Score
16 18.5 19 20
RPS 14 15 19.5 20
“The bottom line”
Frequency of being the best model in 20 casesin terms of
Anomaly Correlation of the Ensemble Mean
“Another bottom line”
CFS ECMWF METFR UKMO
T2m USA 4 5 5 6
T2m EUROPE 3 5 6 5
Prate USA 7 3 3 6
Prate EUROPE 11 0 0 5
Frequency of being the best model in 20 casesin terms of
Brier Score of the PDF
“Another bottom line”
CFS ECMWF METFR UKMO
T2m USA 11 2 1 5
T2m EUROPE 10 3 1 3
Prate USA 17 2 0 1
Prate EUROPE 18 0 1 1
Frequency of being the best model in 20 casesin terms of
Ranked Probability Score (RPS) of the PDF
“Another bottom line”
CFS ECMWF METFR UKMO
T2m USA 9 4 1 6
T2m EUROPE 9 3 4 3
Prate USA 19 0 0 1
Prate EUROPE 18 0 0 1
CONCLUSIONS
• Overall, NCEP CFS contributes to the skill of IMME (relative to DEM3) for equal weights.
• This is especially so in terms of the probabilistic Brier Score
and for Precipitation
CONCLUSIONS (Cont)
In comparison to ECMWF, METFR and UKMO, the CFS as an individual model does:
• well in deterministic scoring (AC) for Prate and• very well in probability scoring (BS) for Prate
and T2m
over both USA and EUROPEAN domains
CONCLUSIONS (Cont)
• The relative weakness of the CFS is in the deterministic scoring (AC) for T2m (which is near average of the other models) over both EUROPE and USA
• Skill (if any) over EUROPE or USA is very modest for any model, or any combination of models
• The Brier Score shows rare improvements over climatological probabilities in this study
• The AC for the ensemble mean gives a more “positive” impression about skill than the Brier Score
Study of the performance of GFDL seasonal forecasts in a
Multi Model Ensemble at NCEP
Huug van den DoolClimate Prediction Center/NCEP/NWS/NOAA
Suranjana SahaEnvironmental Modeling Center/NCEP/NWS/NOAA
Data Used
• 4 initial conditions: April 1, May 1, Oct 1 and Nov 1
• 10 member one-year forecasts (leads 0 thru 11)
• Period 1981-2005 (25 years)
• GFDL has a fully coupled model CM2.1 (IPCC version)
Verification Data Used
• Focus on monthly mean 2m-temperature and precipitation over the continental US
• Verification of 2m-temperature against GHCN+CAMS (land only)
• Verification of precipitation against CMAP ( land and ocean)
• Area: valid grid points (2.5x2.5) within 25N-50N, 125W-65W box over the US
Comparison to the NCEP Climate Forecast System (CFS)
GFDL members start a few days before and on the first of the month.
CFS members are clustered around the 11th and 21st of the previous month and the 1st of the initial month.
In an NCEP operational setting, the GFDL model would be run everyday (similar to the CFS).
Therefore, the calibration of the operational forecast would be obtained from an interpolation of two sets of forecasts, a month apart (one of which would be a month old), thus resulting in a possible degradation of skill.
VERIFICATION OF US PRATE ANOMALY CORRELATION
CFS US PRATE ANOMALY CORRELATIONThere are 32 ENTRIES: 8 leads for 4 initial months
initial month apr may oct novlead
8 .126 .143 .059 .083 7 .135 .174 .101 .034 6 -.001 .071 .081 .112 5 .098 .035 .123 .041 4 .027 .087 .227 .168 3 .049 .025 .166 .231 2 .058 .061 .119 .220 1 .142 .030 .149 .161 0 .191 .244 .189 .277
Worst mean-sd mean mean+sd best -.001 .043 .104 .166 .231
NO CROSS VALIDATION
Some skill in ENSO months
CFS US PRATE ANOMALY CORRELATIONThere are 32 ENTRIES: 8 leads for 4 initial months
initial month apr may oct novlead
8 .062 .093 .007 .024 7 .125 .107 .062 -.017 6 -.090 -.039 .039 .058 5 .038 -.056 .056 -.016 4 -.033 .033 .192 .086 3 -.023 -.073 .120 .191 2 -.028 -.016 .065 .182 1 .113 -.059 .122 .101 0 .139 .241 .116 .248
Worst mean-sd mean mean+sd best -.090 -.032 .045 .121 .192
CROSS VALIDATION CV3RE
CV brings all numbers down
GFDL US PRATE ANOMALY CORRELATIONThere are 32 ENTRIES: 8 leads for 4 initial months
initial month apr may oct novlead
8 .027 .044 .045 .048 7 .122 -.002 .032 .091 6 -.040 .138 .057 .066 5 .003 .047 .113 .016 4 .061 -.019 .153 .081 3 .093 .024 .071 .154 2 .059 .099 .166 .109 1 .120 .074 .085 .217 0 .184 .219 .087 .250
Worst mean-sd mean mean+sd best-.040 .018 .074 .130 .217
NO CROSS VALIDATION
Weak skill in ENSO months
MME2 US PRATE ANOMALY CORRELATION
There are 32 ENTRIES: 8 leads for 4 initial months
initial month apr may oct novlead
8 .104 .135 .065 .082 7 .168 .112 .091 .075 6 -.032 .140 .092 .115 5 .062 .056 .149 .039 4 .060 .043 .241 .159 3 .093 .032 .147 .234 2 .076 .105 .183 .199 1 .165 .067 .145 .227 0 .223 .277 .170 .311
Worst mean-sd mean mean+sd best -.032 .051 .113 .176 .241
NO CROSS VALIDATION
CFS GFDL MME2
22 10
13 19
3 28
.045 .009 .035
CFS GFDL MME2
21 11
20 12
12 20
.104 .074 .113
NO CV
CV3RE
US PRATE (AC)BEST out of 32 cases (4 IC’s x 8 leads):
MEAN AC
MEAN AC
CFS alone is slightly better than GFDL alone
MME2 is slightly better than CFS alone
MME2 is better than GFDL alone
Numerically, differences are minuscule, and the existence of any skill is debatable
US PRATE (summary)
• Adding GFDL to CFS for MME2 degrades scores
• GFDL has ENSOs, maybe even too strong in 1983 and 1998, but
the precipitation anomalies are weak at the equator and are pushed
away from the equator, mainly into the southern hemisphere.
PRATE OVER NINO 3.4 AREA (summary)
CFS MME2 GFDL .532 .520 .313 (NO CV).511 .481 .252 (CV3RE)
VERIFICATION OF US SURFACE TEMPERATURE
ANOMALY CORRELATION
CFS GFDL MME2
13 19
13 19
19 13
.026 .029 .009
CFS GFDL MME2
15 17
13 18
13 18
.080 .099 .113
NO CV
CV3RE
US 2m TEMPERATURE (AC)BEST out of 32 cases (4 IC’s x 8 leads):
MEAN AC
MEAN AC
CFS alone is not better than GFDL alone
MME2 is slightly better than CFS alone
MME2 is not better than GFDL alone
Numerically, differences are minuscule, and the existence of any skill is debatable
US 2m TEMPERATURE (summary)
Effect of OCN (Optimal Climate Normals)
filtering on AC scores for all 32 cases
(NO-CV)
9 year running mean is removed
RAW OCN-filtered
GFDL 0.099 0.068
CFS 0.080 0.073
• GFDL loses its advantage over the CFS
when the trend is removed
TREND ANALYSIS OF US 2m TEMP
CONCLUSIONS (1)
• Skill of both, CFS and GFDL, is extremely low for both 2m temperature (T2M) and precipitation (PRATE) over the US, and this skill wilts further upon cross validation (CV3RE)
• GFDL makes no contribution to the skill of MME2 for PRATE over the US
• GFDL makes no contribution to the skill of MME2 for PRATE over the tropical Pacific (Nino 3.4 area)
• GFDL has a small edge over the CFS and contributes to MME2 for T2M over the US
CONCLUSIONS (2)
• The inconsistency between performance in PRATE and T2M is explained by inclusion of historical CO2 etc, i.e. GFDL does a better job on the decadal temperature trends. This is explained by the drop in the skill when the trend is removed.
• The empirical tool, OCN (Optimal Climate Normals), is routinely used by CPC to incorporate decadal trends in the consolidation of the official seasonal forecasts for US T2M. Its performance is better than any of their dynamical tools.
From Delsole(2007)• Surprisingly, none of the regression
models proposed here can consistently beat the skill of a simple multi-model mean
• “Under suitable assumptions, both the Bayesian estimate and the constrained least squares solution reduce to standard ridge regression”.
Kharin and Zwiers(2002):• Several methods of combining individual forecasts
from a group of climate models to produce an ensemble forecast are considered
• In the extratropics, the regression-improved ensemble mean performs best.
• The “superensemble” forecast that is obtained by optimally weighting the individual ensemble members does not perform as well as either the simple ensemble mean or the regression-improved ensemble mean.
• The sample size evidently is too small to estimate reliably the relatively large number of optimal weights required for the superensemble approach.
FinallyHuug van den Dool, 2007
• There is essentially not enough hindcast data for these fancy consolidation methods to work (21-25 years is nothing !!). ((There may be exceptions))
• There is no (or not enough) independent information in model A versus Model B
• We have to be rigorous in CV procedures!
The rest is EXTRA
Classic +Delsole limit
+CPC limit
Appendix: Consolidation Techniques• A technique to linearly combine any set of models Example: Con3 = a*A + b*B + c*C, where A, B and C are forecasts and a, b, and c coefficients.
• The coefficients ideally depend on skill and co-linearity among the models, as determined from many hindcasts
• Because of near instability of the matrix problem, NCEP applies ‘ridging’ to the covariance matrix, and tries to pool as much data as possible (areas, leads..).
• To arrive at a skill estimate, we perform a 3 year-out cross validation (CV3), namely the year in consideration and two more years chosen at random (to reduce CV pathological problems)
BRIER SCORE FOR 3-CLASS SYSTEM
1. Calculate tercile boundaries from observations 1981-2001 (1982-2002 for longer leads) at each gridpoint.
2. Assign departures from model’s own climatology (based on 21 years, all members) to one of the three classes: Below (B), Normal (N) and Above (A), and find the fraction of forecasts (F) among all participating ensemble members for these classes denoted by FB, FN and FA respectively, such that FB+ FN+FA=1 .
3. Denoting Observations as O, we calculate a Brier Score (BS) as :BS={(FB-OB)**2 +(FN-ON)**2 + (FA-OA)**2}/3, aggregated over all years and all grid points.
{{For example, when the observation is in the B class, we have (1,0,0) for (OB, ON, OA) etc.}}
4. BS for random deterministic prediction: 0.444 BS for ‘always climatology’ (1/3rd,1/3rd,1/3rd) : 0.222
5. RPS: The same as Brier Score, but for cumulative distribution (no-skill=0.148)
0
20
40
60
80
100
Anom
aly
Corr
ela
tion
0 2 4 6 8 10 12 14forecast day
gfdl m06 cfs m11
Daily Raw Z500 Scores1981-2005 NH (IC=Oct30,0Z)
Anomaly correlation does not asymptote to 100 at fcst time=0Interpolation of initial conditions from Reanalysis 2 may not be correct or accurate
CROSS-VALIDATION
Anomaly Pattern correlation over the tropical Pacific. Average for all leads and initial months. Empty bar: Full (dependent), filled bar: 3-yr out cross-validated.
30
40
50
60
70
80
90
D1 D2 D3 D4 D5 D6 D7 CFS CA MM COR FRE RID RI2 RIM RIW UR
Peña and Van den Dool (2008)Consolidation of Multi Method Forecasts by Ridge Regression:
Application to Pacific Sea Surface Temperature
Strategies to increase the ratio of the effective sample size of the training data to the number of coefficients to be fitted are proposed and tested. These strategies include:
• i) objective selection of a smaller subset of models, ii) pooling of information from neighboring gridpoints, and iii) consolidating all ensemble members rather than each model’s ensemble average.
• In all variations of the ridge regression consolidation methods tested, increased effective sample size produces more stable weights and more skillful predictions on independent data.
• In the western tropical Pacific, most consolidation methods outperform the simple equal weight ensemble average; in other regions they have similar skill as measured by both the anomaly correlation and the relative operating curve.
• The main obstacle to progress is a short period of data and a lack of independent information among models.
• CV3RE