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AIFS Single v2 and AIFE ENS v2

Implementation of the Integrated Forecasting System (IFS) Cycle 50r1 in May 2026 introduced several improvements, including stronger ocean–atmosphere coupling, a new version of the NEMO ocean model, and updated sea-ice representations.  This meant that biases in training data changed significantly - rather more than in typical IFS model upgrades.   However, the changes pave the way for ocean–atmosphere coupled versions of the AIFS.

Improvements introduced in Cy50r1 alter the characteristics of the analysis used to initialise forecasts and improve the representation of key physical processes.   Moreover, they also have consequences on data-driven models and specifically the Artificial Intelligence Forecasting System (AIFS).

The difficulty in producing an accurate forecast rises with forecast lead-time.  Both broad scale accuracy and fine scale variability are desirable.  However, both cannot be captured at the same time with a single forecast at longer time ranges.  In the case of less predictable weather situations, smoother forecasts (such as the ensemble mean) provide on average lower forecast errors.  ML-based forecasts show less energy at smaller scales and patterns ack detail.  This loss of energy at synoptic scales is particularly strong at day 6 and day 10.

(Note: this is not the case for the IFS forecasts, which have an energy spectrum that barely changes with lead time). 

Training

Machine learning (ML) training for AIFS v2 and AIFS ENS v2 included some Cy50 (pre-operational) ERA5 data with Cy49 (operational at the time) ERA5 data.  Fine tuning was based on a seven-year fine-tuning dataset also included Cy50 data. 

This training on more up-to-date data ensures AIFS continues to perform well under the new conditions,

Fine Tuning

Fine-tuning is a strategy used to mitigate a change in the IFS model (from Cy49 to Cy50) used in the analyses and re-analyses.  These in turn affect the learning process for the AIFS models.  Fine-tuning for AIFS involves adapting pre-trained weights to specific regions, higher resolutions, or new physical variables. Also, further training on forecast analyses (rollout) improves location accuracy in long-term forecasts but suppresses fine-scale variability and smoother forecasts.  Thus there is a trade off between accuracy of location, or in the detail of depth or complexity of a forecast system.   This is particularly important in forecasting tropical cyclones.


Parameters forecast by AIFS Single v2 and AIFS ENS v2

The release in May 2026 of AIFS v2 introduces:

  • A new wave component, including 11 wave variables, marking ECMWF's first operational data-driven wave forecasts.
  • The addition of a new snow variable to the existing land component.
  • The addition of tropical cyclone track forecasts.
  • The addition of two variables (vsw and cp) to AIFS ENS (These are already present in AIFS Single).
  • Improved vertical velocities, by changing parameter W from a prognostic to a diagnostic field.
  • An improved representation of the stratosphere, with the addition of pressure level fields at 10hPa.


List of parameters

New parameters in bold.


Field

Level type

Input/Output

Geopotential (Z),

Horizontal & Vertical wind components (U, V),

temperature (T)

Pressure levels: 10, 50, 100, 150, 200, 250, 300, 400, 500, 600, 700, 850, 925, 1000

Both

("Prognostic")

Specific humidity (Q)

Pressure levels: 100, 150, 200, 250, 300, 400, 500, 600, 700, 850, 925, 1000

Both

("Prognostic")

Vertical velocity (W)

Pressure levels:

10, 50, 100, 150, 200, 250, 300, 400, 500, 600, 700, 850, 925, 1000

Output

("Diagnostic")

Specific humidity (Q)

Pressure level: 50

Output

("Diagnostic")

Surface pressure (SP),

Mean sea-level pressure (MSL),

Sea-surface temperature (SST),

Skin temperature (SKT),

2m temperature (2T),

2m dewpoint temperature (2D),

10m horizontal wind components (10U, 10V),

Total column water (TCW),

Mean wave period (MWP),

Mean wave direction (MWD),

Coefficient of drag with waves (CDWW),

Significant wave height (SWH), all waves with periods within the inclusive range from:

·      10 to 12 seconds (H1012)

·      12 to 14 seconds (H1214)

·      14 to 17 seconds (H1417)

·      17 to 21 seconds (H1721)

·      21 to 25 seconds (H2125)

·      25 to 30 seconds (H2530)


Surface

Both

("Prognostic")

Volumetric soil moisture (VSW) and

Soil temperature (SOT),

both at soil depth 1 and 2

Soil layer

Both

("Prognostic")

100m horizontal wind components (100U, 100V),

Surface short-wave (solar) radiation downwards (SSRD),

Surface long-wave (thermal) radiation downwards (STRD),

Cloud variables (TCC, HCC, MCC, LCC),

Runoff water equivalent (ROWE),

Snow fall (SF),

Total precipitation (TP),

Convective precipitation (CP),

Fraction of snow cover (FSCOV)

Surface

Output

("Diagnostic")

Standard deviation of sub-gridscale orography (SDOR),

Slope of sub-gridscale orography (SLOR),

Land-sea mask (LSM),

Geopotential (Z),

Insolation,

Latitude/longitude,

Time of day/day of year

Model bathymetry

Surface

Input

("Forcings")




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