Title: Preliminary%20Results%20from%20CliPAS/APCC%20Multi-Model%20Ensemble%20Hindcast%20Experiments
1Preliminary Results from CliPAS/APCC Multi-Model
Ensemble Hindcast Experiments
Bin Wang and June-Yi Lee IPRC/ICCS, University of
Hawaii, USA In-Sik Kang Seoul National
University, Seoul, Korea Chung-Kyu Park APCC,
Busan, Korea
Acknowledge contributions from all CliPAS
investigators
2About APCC
APEC (Asia-Pacific Economic Cooperation)
APCN (APEC Climate Network)
APCC
(APEC Climate Center)
3APEC Participating Member Economies
4Background From APCN to APCC
APCN, The APEC Climate Network, is a regional
climate program aimed at realizing the APEC
vision of regional prosperity through mitigation
of economic losses induced by abnormal
climate. APCN produces real-time operational
climate prediction information based on a
well-validated multi-model ensemble system
(MMES).
In order to enhance the activities of APCN,
Korea proposed and the APEC Science and
Technology Ministry endorsed establishment of
APEC Climate Center (APCC) in Korea with a core
staff of scientists and computing facilities.
The APCC Opening Ceremony will be held on
18-20th November 2005 during the APEC Summit
Meeting in Bussan, Korea,.
5APCC is an international institute and serves as
a hub for APEC regional climate research and
prediction
To make an effort toward accomplishing the
WCRP/COPES vision
To provide core facilities and man powers to
accomplish the vision.
6CliPAS
Climate Prediction and Its Application to
Society A Joint US-Korea Research Project in
Support of APCC
Objectives Investigate a set of core scientific
problems on multi-model ensemble (MME) climate
prediction Establish well-validated MME
prediction systems for intraseasonal and seasonal
prediction Develop economic and societal
application models.
7Participating Institutions in CliPAS
APCC
IPRC- ICCS / UH
KMA
CES/SNU
NCEP
COLA
GFDL
NASA
FRCGC
FSU
8CliPAS Investigators (Oct. 2005)
PI Bin Wang (UH/IPRC/ICCS)
Co-PIs J. Shukla (GMU/COLA), I.-S. Kang (CES/SNU), L. Magaard (ICCS/UH)
Co-Is J.-Y. Lee (UH/ICCS) B. Kirtman, J. Kinter (GMU/COLA) T. Krishnamurti, Steven Cocke (FSU), N.C. Lau, T. Rosati, W. Stern (NOAA/GFDL), M. Suarez, S. Schubert, W. Lau (NASA/GSFC), A. Kumar , J. Schemm (NOAA/NCEP), J.-S. Kug (CES/SNU), W.-T. Yun (KMA) C.-K. Park (APCC), S, Kar (APCC), J.-J. Luo (FRCGC/JAMSTEC), T. Yamagata (UT) J. Marsh (UH/ICCS), W.-D. Grossmann (GKSS/ICCS)
9APCC/CliPAS Project
RESEARCH THRUST AREAS
- Establish a pilot operational APCC-MME SPS
- New methodology for integrating MME predictions
- Strategy for Intraseasonal prediction
- Interactive multi-model ensemble prediction
experiment
- Coupled model initialization and data
assimilation - Perturbed physics experiments
- Climate information system model and
socio-economic value assessment models
10Current CliPAS/APCC MME Hindcast Experiments
Two-Tier systems
One-Tier systems
SNU SST prediction system
CGCM
AGCM
NASA
CFS/NCEP
FSU
GFDL
SNU
CAM2 (UH)
SINTEX-F
SNU/KMA
ECHAM(UH)
Hybrid CGCM (UH)
- 1981 2004 summer and winter season for 24
years - Summer from May 1 to September 30
- Winter from November 1 to March 31
Experiment Period
11MME Hindcast Skill Temporal Correlation/
1981-2001
2m Air Temperature
DEMETER MMEP
APCC MMEP
Summer Mean Prediction
Winter Mean Prediction
12(No Transcript)
13MME Hindcast Skill Taylor Diagram/ 1981-2001
2m Air Temperature
DEMETER MMEP
APCC MMEP
JJA
DJF
14MME Hindcast Skill Temporal Correlation/
1981-2001
Precipitation
APCC MMEP
DEMETER MMEP
JJA
DJF
15MME Hindcast Skill Taylor Diagram /1981-2001
Precipitation
DEMETER MMEP
APCC MMEP
JJA
DJF
16MME Effective Index/ Precipitation
DJF
JJA
17Wang et al. (2004)
18(No Transcript)
19Correlation Coefficients between the observed and
5 AGCM MME hindcasted June-August precipitations
(1979-1999)
Wang et al. (2005)
Fig. 1
20Area averaged correlation coefficients (skills)
21MME Hindcast Skill in AAM region 1981-2001
Precipitation
Southeast Asian and WNP region 80-150E, 5-30N
DEMETER MMEP
APCC MMEP
JJA
DJF
22MME Effective Index/ Precipitation
DJF
JJA
Southeast Asian and WNP region 80-150E, 5-30N
23One-Tier 1 vs Two-Tier Anomaly PCC over AAM (JJA)
ENSO vs Precipitation SST vs.
Precipitation
24Probabilistic MMEP Range of Area of ROC Curve/
Above Normal Precipitation
APCC
DEMETER
JJA
DJF
Probabilistic forecast for above normal
precipitation greater than 0.5 standard deviation
25Deterministic and Probabilistic MMEP Potential
Economic Value/ Above Normal 2m Air Temp
APCC
DEMETER
Probabilistic forecast for above normal 2m air
temperature greater than 0.5 standard deviation
over ENSO Region
26- Summary of the Preliminary Results
- The CliPAS blended one- and two-tier MME
hindcasts - have skills comparable to DEMETER in
precipitation and - surface temperature prediction, although their
individual - modles performance is lower that those of
DEMETERs. - b. The CliPAS MME is more effective due to their
larger - mutual independence as evidenced from their
larger - range of their skills .
- c. The MME is more effective when and where
individual - models have moderate performances while
potential - predictability is large. MME is more applicable
to the - summer monsoon regions.
- d. In A-A summer monsoon heavy precipitation
regions, - one-tier is superior to two-tier system due to
increased - feedback from the local surface SST and improved
ENSO - teleconnections.