“Behind good forecast practices are often hidden good theories; equally, good theories should provide a basis for good forecast practices” Professor Tor Bergeron, personal communication, 1974
This edition of the Forecaster User Guide applies to the ECMWF Integrated System (IFS) and meteorological products after autumn 2024 using IFS Cycles 49r1 and later. We are also now starting to add guidance on the AIFS (a data-driven / machine learning model).
With effect from Cy49r1, HRES and Ensemble Control are scientifically, structurally and computationally identical with 9km resolution and their products are known as Control Forecast (ex-HRES).
Note: HRES and Ensemble Control Forecast (ex-HRES) are scientifically, structurally and computationally identical. With effect from Cy49r1, Ensemble Control Forecast (ex-HRES) output is equivalent to HRES output where shown in the diagrams. At the time of the diagrams, HRES had resolution of 9km and ensemble members had a resolution of 18km.
Also with effect from Cy49r1 the extended range forecast is now known as the sub-seasonal forecast.
An alternative name for Ensemble Control Forecast (ex-HRES) is IFS-CF.
Alternative names for Sub-seasonal Forecast are IFS-SUBS, IFS-SSP, or IFS-S2S
The aim of this User Guide is to help meteorologists make the best use of the forecast products from ECMWF.
In particular the aims of the guide are:
The goal of ECMWF is to produce:
The IFS configurations are:
The ECMWF model output is delivered in the form of charts or GRIB format datasets. It is readily available to forecasters via:
The ECMWF IFS is upgraded at roughly yearly intervals to incorporate improved representation of physical processes and/or resolution changes. New products increasingly aid early warning of severe or hazardous weather. Information on the latest upgrade is given below.
The User Guide is broadly divided into two parts. Sections 2 to 5 describe the structure of the ECMWF Integrated Forecasting System. Sections 6 to 11 describe how the IFS may be used to best advantage by forecasters.
There are links to more detailed descriptions of processes, mainly at the end of each section. Separate online ECMWF training resources explain aspects of the ECMWF IFS more visually.
A key component of the work at ECMWF is education and training. Further educational material is available through the web site:
ECMWF Newsletters issued quarterly give information on IFS models and applications and ECMWF plans.
A glossary is included in Appendix 12C.
Section 2 describes in broad, non-technical terms the ECMWF Integrated Forecast System (IFS). This comprises the global atmospheric model, the wave and the oceanic dynamical models, and the data assimilation systems. It gives an overview of the way the atmospheric model uses sub-gridscale parameterisations and atmospheric physics for processes within the atmosphere and at the surface. There are large differences in energy fluxes between land or sea and the atmosphere. Thus the definition of the model coastline by the land-sea mask is extremely important. This is especially true for meteograms in coastal areas or on islands.
Numerical weather prediction (NWP) output is complicated by its often counter-intuitive and non-linear behaviour. Understanding model processes enables forecasters to assess model output critically.
Section 3 gives an overview of the way ECMWF graphical forecast products are presented to the forecaster. It gives some insights into ways the analysed and forecast data may be reduced in accuracy by the way it is presented.
Section 4 discusses model error growth with time and the relationship between predictability and scale. An indication is given of how anomalies propagate downstream and gives some pointers towards recognition of these in the analysis.
Section 5 describes the way the members of the ensemble are generated. The use of ENS allows assessment of uncertainty in the model forecast by giving a range of results. Each ensemble member starts from slightly perturbed initial data. Consequently each evolves a little differently from the other members of the ensemble to give a range of possible forecast results. The variation seen within the ensemble forecasts gives an indication of predictability of the atmosphere.
Model climates are an important product produced within the IFS. These are: M-climate for medium range ensemble, SUBS-M-Climate for sub-seasonal range ensemble, S-M-climate for seasonal forecasting ensemble. They are a wholly model-based assessment of worldwide climatology based on analyses and re-forecasts over a previous period of 20 or 30 years.
Section 6 discusses the reliance that can be placed upon the ensemble as the forecast lead-time increases. Each slightly perturbed ensemble member evolves a little differently from the others and gives a range of possible forecast results. The variation seen within the ensemble forecasts gives an indication of predictability of the atmosphere. The use of probabilities or other risk assessments is an essential part of building forecasts useful to the customer. This section emphasizes the benefit of using ensemble products to get the best description of evolution and uncertainty of a forecast.
Section 7 concentrates on methods that may be used to assess confidence in model results. This section gives guidance on interpretation of latest and previous ensembles output to allow insight into the uncertainty of the forecast. It also gives guidance on assessing the skill of a forecast and how to use run-to-run variability in the forecasts to best advantage. The continuing role of the human forecaster is emphasized.
Section 8 concentrates on making best use of the extensive range of products that are available. The IFS produces a very wide range of products which is delivered in the form of charts or GRIB format datasets. It is readily available to forecasters via:
Model products may be deterministic, probabilistic, or in the form of anomalies from normal as defined by model climates. Ensemble output is shown in an easy-to-use form as:
The model climates are used extensively to highlight locally extreme weather conditions for time of year and for forecast lead time. The Extreme Forecast Index (EFI), pioneered at ECMWF, compares the forecast probability distribution with the corresponding model climate distribution. The Shift of Tails (SOT) index complements the Extreme Forecast Index (EFI) by giving information about how extreme an event might be. This is done by comparing the tail of the ensemble distribution with the tail of the M-climate.
The overall aim is to allow assessment of uncertainty to provide the customer with the best and most useful guidance possible.
Section 9 gives pointers towards features which can have an impact on model output. This allows users to modify and improve forecasts for issue to customers. Some other short-comings of the models are noted. These will be addressed in the future but meanwhile they need to be considered by the forecaster. It is through forecaster user feedback that important points will be identified and addressed. The importance of critical assessment of model output by human forecasters cannot be understated.
Section 10 gives an outline of the way forecast data may be presented to the user. ECMWF Web Charts (Open Access) give easy access to ECMWF IFS output. The more flexible and interactive ecCharts allows users to pick-and-mix the IFS data.
Section 11 highlights the continuing importance of the forecaster in providing a consistent and useful product to the customer.
Section 12 contains additional detail on statistical concepts for verifying model forecasts, the current structure of IFS, and a list of acronyms.
The forecaster is not a computer. Instead, the forecaster is employed to add value to model forecasts, and to identify and quantify uncertainties. Forecasters should provide a balanced assessment of the probability of an event that is relevant to customer requirements.
Daily operational forecasting work is largely a matter of assessing, interpreting, combining and correcting NWP information. Also vital is the ability to identify quickly those products that are particularly relevant for a given synoptic situation. In the medium-range especially, the use of statistical know-how counts as much as synoptic experience.
Forecasters, and other users, should not simply follow NWP guidance. They should act quite differently by:
ideally, not giving sudden “U-turns” in guidance.
Some major model changes were made to the IFS with the introduction of Cy49r1 in October 2024. These are:
Note:
HRES and Ensemble Control (ex-HRES) are are scientifically, structurally and computationally identical. HRES output is maintained for the convenience of users but will be withdrawn in a future update cycle.
The sub-seasonal range ensemble forecasts (formerly extended range forecasts) are not just an extension of the medium range forecasts but are completely separate forecast systems. However, both start from very similar analyses. There are two sets of re-forecasts, one for the medium range and one for the sub-seasonal range.
Full details of the current Integrated Forecast System (IFS) is given in the official ECMWF IFS documentation of CY49r1.
Users are advised to keep themselves updated about changes and improvements to products and model processes through the ECMWF Newsletter and web site (e.g. via the Forecast User portal)
(FUG Associated with Cy49r1)
This User Guide has been compiled by Bob Owens, with assistance from Tim Hewson, and with contributions from many other scientists and ex-forecasters at ECMWF. It is an updated version of the "User Guide to ECMWF Forecast Products" written originally by Anders Persson and published in 2011 (that had minor adjustments in 2013 and 2015).
The User Guide should be cited as follows: Owens, R G, Hewson, T D (2018). ECMWF Forecast User Guide. Reading: ECMWF. doi: 10.21957/m1cs7h