The development of GRAPES_RAFS and its applications
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Transcript of The development of GRAPES_RAFS and its applications
The development of GRAPES_RAFS and its applications
Xu Zhifang Hao Min Zhu Lijuan Gong Jiangdong Chen DehuiNational Meteorological Center, CMA
Wan Qilin
Guangzhou Institute of Tropical and Marine Meteorology, CMA
(24 October, 2011, for Workshop-NWP Nowcasting in Boulder-USA)
Outline• 1 Introduction• 2 RAFS Based on GRAPES_Meso• 3 Results of some experiments• 4 Plans for future work
1 Introduction
The requirements are increasing in short-term forecasts of the severe high impact weather which occurred more frequently in recent years in China.
1 IntroductionSever thunderstorm in He-nan ( 河南 ) on June, 2009
Mud-rock flow on August 07, 2010 in Zhou-qu ( 舟曲 )
1 Introduction (cont.)
• Many data sets from different obs. systems (AWS, aircraft, GPS, radars, satellites) have been frequently (hourly or shorter) are available in real time.
(Meng Zhaolin , 2011)
2 RAFS Based on GRAPES_Meso
Flow Chart of Grapes_RAFS
Data processing
ObservationDATA A
ssimilation
C
ycle
FirstguessForecast
Digital Filter initialization
DFI
GRAPES_ MODELGRAPES-Model
background
GRAPES_ 3DVARGRAPES-3DVar
Cloud Analysis
nudging
Data Assimilation
– Radio sonde data (wind, temperature, humidity, pressure)
– AWS data (pressure)– VAD winds (Doppler Radar)– GPS/PW– Ship reports (pressure)– Aircraft (wind, temperature)– FY-2C/2D cloud-drift winds – Cloud Analysis (Radar , Satellite data,
surface observation et al.)
Data can be used in GRAPES_3DVAR :
3 Results of some experiments
3.1 Design of the experiments
– GRAPES_Meso: 15km L31– GRAPES_3DVAR (model grid space)– 1-hourly cycle rapid analysis– 12 hour forecast at
03,06,09,15,18,21UTC– 24 hour forecast at 00,12UTC– Data used: GTS, local radiosonde,
Doppler radar VAD, AWS, Aircraft
3.1 Design of the experiments
VADRadiosonde
SYNOPAIREP
Horizontal distribution of one case
3.2 Verification
left : observation (radar reflectivity)
right : model forecasting ( Initial time : 0300GMT 3 June, 2009 )
The position prediction of strong convective system is very close to the observation.
The moving direction of the system is close to observation
left : observation (radar composite reflectivity)
right : model forecasting ( Initial time : 0600GMT 3 June, 2009 )
2009 6- 8 00- 06 6 TS TS Score年 月 全国区降水 小时 评分
0
0. 05
0. 1
0. 15
0. 2
0. 25
0. 3
0. 35
0. 4
0. 45
6月 7月 8月months
RUC_小雨OPT_小雨RUC_中雨OPT_中雨RUC_大雨OPT_大雨RUC_暴雨OPT_暴雨
2009 6- 8 12- 18 6 TS TS Score年 月 全国区降水 小时 评分
0
0. 05
0. 1
0. 15
0. 2
0. 25
0. 3
0. 35
0. 4
0. 45
6月 7月 8月months
RUC_小雨OPT_小雨RUC_中雨OPT_中雨RUC_大雨OPT_大雨RUC_暴雨OPT_暴雨
Initial Time : 0000GMT Initial Time : 1200 GMT
(TS score) (TS score)
TS-Verification of 6h accumulated precipitation over whole Chinafor the period of June-August 2009
Inter-comparison between GRAPES_RAFS (RUC) with operational GRAPES_Meso (OPT): TS of RAFS is better than that of OPT for all thresholds: 0.5mm, 5mm, 10mm, above 15mm.
2009 6-8 24 TS年 月 小时降水 评分
0
0. 1
0. 2
0. 3
0. 4
0. 5
0. 6
0. 7
6月 7月 8月
RUC_小雨OPT_小雨RUC_中雨OPT_中雨RUC_大雨OPT_大雨RUC_暴雨OPT_暴雨
TS-Verification of 24h accumulated precipitation over whole China
for the period of June-August 2009
Inter-comparison between GRAPES_RAFS (RUC) with operational GRAPES_Meso (OPT): TS of RAFS is better than that of OPT for all thresholds: 1mm, 10mm, 25mm, above 50mm.
1mm
10mm
25mm
50mm
(TS score)
(Wang Yu ,2007)Sub-domains for verifications
1 North-Eastern
2 Xinjiang
3 East of West-Northern
4 North of China
7 M. & D. basins of Yangtz River
8 South of China
5 Tibetan Plateau
6 East o
f West-
So
uth
ern R
.
TS-Verification of 6h accumulated precipitation forecasts over whole China for the period of June-August 2011: RAFS vs OPT.
1 2 3 4 5 6 7 81 2 3 4 5 6 7 8
1 2 3 4 5 6 7 8 1 2 3 4 5 6 7 8
Threat ScoreBias
Threat Score Bias
3.3 Recent updates
(1)
Old vertical correlation: too big from bottom to top
V. Potential
HumidityS. function
Pressure
new vertical correlation: reduced significantly
S. function
Humidity
Pressure
V. potential
Red: with old background covariance ; Grey: with new background covariance
0.1 10 25 50 100 (mm)
0.1 10 25 50 100 (mm)
0.1 10 25 50 100 (mm)
0.1 10 25 50 100 (mm)
TS-Verification of 6h accumulated precipitation over whole ChinaPeriod: 072009
I. Time: 06Z
Period: 072009
I. Time: 18Z
Period: 082009
I. Time: 06ZPeriod: 082009
I. Time: 18Z
Red: with old background covariance ; Grey: with new back-ground covariance
0.1 10 25 50 100 (mm)
0.1 10 25 50 100 (mm)
TS-Verification of 24h accumulated precipitation over whole China for August (left), July (right) 2009
Configurations• GRAPES_Meso 3.0
15km L31 with m-top at 10 hPa•Radiation: no-change•Cumulus: Betts-Miller-Janjic•Microphy.: WSM-6 (soon by 2-momment (Liu, 2010))•Cloud: no-change•Land surface: NOAH •PBL: no-change•q-adv.: PRM(Xiao, 2002)
• GRAPES_Meso 2.5
15km L31 with m-top at 10 hPa•Radiation: RRTM LW & Dudhia SW•Cumulus: SAS•Microphy.: WSM-6•Cloud: Xu & Randall diagnostic cloud•Land surface: SLAB•PBL: MRF PBL•q-adv.: QMSL
Grey: with GRAPES_V2.5; Pink: with GRAPES_V3.0
0.1 10 25 50 100 (mm) 0.1 10 25 50 100
(mm)
0.1 10 25 50 100 (mm)
0.1 10 25 50 100 (mm)
TS-Verification of 6h accumulated precipitation over whole ChinaPeriod: 072009
I. Time: 06Z
Period: 072009
I. Time: 18Z
Period: 082009
I. Time: 06Z
Period: 082009
I. Time: 18Z
Grey: with GRAPES_V2.5; Pink: with GRAPES _V3.0
0.1 10 25 50 100 (mm)
0.1 10 25 50 100 (mm)
TS-Verification of 24h accumulated precipitation over whole China for July (left), August (right) 2009
4 Plans for future work
4 Plans for future work
To Improve QC scheme and assimilation approach of local intensified observation.
To make better use of satellite data. To perform the cloud analysis. To improve boundary layer and cloud
microphysical process in GRAPES model. To add 1DVAR assimilation of precipitations
Thanks for your attention