- Created by Helen Setchell, last modified by Kathy Maskell on Jan 25, 2023
Description of the upgrade
The new cycle includes a collection of improvements to the forecast model and the data assimilation system. The cycle also contains hourly post-processing of model data to 90 hours in support of the Boundary Conditions (BC) Optional Programme, including hourly wave data for all four forecast cycles. Hourly post-processed products will also be introduced for the European limited area wave model. Technical changes affecting three products (10m wind gusts, maximum and minimum 2m temperature) that require action by users are detailed in Annex B of this message. The main differences between cycle 37r3 and the current operational version (cycle 37r2) in terms of their meteorological impact are shown on this page.
Implemented: 15 November 2011
Datasets affected
ENS
Resolution
Unchanged
Horizontal | Vertical |
---|---|
Atmospheric (unchanged)
Wave (unchanged)
| Atmospheric (unchanged)
|
Meteorological content
- Modification of the entrainment/detrainment of convection
- Modification of the supersaturation and deposition rate for clouds
- Modification of the surface roughness
- Bias correction of aircraft temperature observations
- Cycling of stratospheric model error (for the weak-constraint 4D-Var)
- Assimilation of accumulated rainfall from NEXRAD radar data from the United States
- Assimilation of ozone observations from infrared radiances
- Use of the latest version of the NWP-SAF radiative transfer model (RTTOV-10 including FASTEM-4)
- Retuning of cloud detection for the advanced infrared sounder data
Changes specifically to the EPS
- Use of the NEMO ocean model (instead of HOPE) in EPS and use of the NEMOVAR ocean data assimilation system
- Coupling of the EPS to the ocean model also at 12 UTC as of day-10 (previously done at 00 UTC, only)
Meteorological impact
The impact of the new cycle on the performance of the forecasting system has been tested in research mode during the period 1 January to 10 May 2011, and in pre-operational runs since 11 May 2011. The new cycle shows benefit in terms of objective upper-air scores in the early forecast range in both hemispheres: the geopotential scores are improved throughout the troposphere, with some degradation at the 100 hPa level. Tropical wind scores in the lower troposphere are significantly improved, specifically leading to reduced systematic errors in the strength of the low level inflow to the African and Indian monsoons. The change in surface roughness has led to reduced 10m wind speed over land and reduced diurnal amplitude in T2m, both of which result in generally reduced bias against observations. Cold biases in T2m have been reduced in specific winter-time situations where the amount of super-cooled cloud-water has been increased. The main impact on the EPS is improved probabilistic scores for the tropical winds throughout the forecast range.
- Impact on upper-air scores in the early forecast range in both hemispheres
- Impact on geopotential scores
- Lower tropical wind scores
- Impact on the EPS is improved
Evaluation
See scorecard in Newsletter No.130 Winter 2011/12: pages 13-14
New and changed parameters
New parameters
None
Changes to existing parameters
None
Technical content
Model ID and experiment number
Model ID = 37r3
E-suite experiment number = 0055
Resources
ECMWF Newsletter: See Newsletter 130 pages 4 and 13-14
See our Related News Item (24 Nov 2011)
The main changes to the atmospheric model are the modifications of entrainment and detrainment in convection, of supersaturation and deposition rates in clouds, and of surface roughness. The changes to the convection scheme produce a significant positive impact on near-surface temperature and wind forecasts in the Tropics
The update of supersaturation and deposition rates in clouds mostly affects the amount of liquid water in supercooled clouds, leading to reduced night-time cooling and thus reduced cold temperature biases in certain winter situations at high latitudes.
Variable bias corrections for aircraft temperature observations, the assimilation of rainfall measurements from NEXRAD radars over the United States, and the assimilation of ozone measurements from infrared satellite instruments were also introduced. These changes increase the number of observations used in the data assimilation system and enhance the physical consistency of temperature and moisture analysis.
The main changes to the ensemble prediction system (EPS) are the use of the NEMO ocean model (instead of HOPE) and the NEMOVAR ocean data assimilation system. Now, the 12 UTC EPS run is also coupled to the ocean model from day10 onwards; previously only the 00 UTC run was coupled.
Users of ECMWF’s web pages may have noticed that most of the displayed forecast charts are now being produced with the new version of the ECMWF visualisation software, Magics++.
- Terminology for IFS testing
- Implementation of IFS Cycle 48r1
- Implementation of IFS Cycle 47r3
- Implementation of IFS Cycle 47r2
- Implementation of IFS Cycle 47r1
- Implementation of IFS cycle 46r1
- Implementation of IFS cycle 45r1
- Implementation of Seasonal Forecast SEAS5
- Implementation of IFS cycle 43r3
- Implementation of IFS Cycle 43r1
- Implementation of IFS cycle 41r2
- Introducing the octahedral reduced Gaussian grid
- Horizontal resolution increase
- Boundary-Condition Programme ENS at 06 and 18 UTC
- Implementation of IFS Cycle 41r1
- IFS cycle upgrades pre 2015