Graph Machine Learning
AnemoI
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AIFS Single - v0.2.1

Here, we introduce the Artificial Intelligence Forecasting System (AIFS), a data driven forecast model developed by the European Centre for Medium-Range Weather Forecasts (ECMWF).

AIFS 10 days Forecast

We show that AIFS produces highly skilled forecasts for upper-air variables, surface weather parameters and tropical cyclone tracks. AIFS is run four times daily alongside ECMWF’s physics-based NWP model and forecasts are available to the public under ECMWF’s open data policy. (https://www.ecmwf.int/en/forecasts/datasets/open-data)

Model Details

Model Description

AIFS is based on a graph neural network (GNN) encoder and decoder, and a sliding window transformer processor, and is trained on ECMWF’s ERA5 re-analysis and ECMWF’s operational numerical weather prediction (NWP) analyses.

Encoder graph Decoder graph

It has a flexible and modular design and supports several levels of parallelism to enable training on high resolution input data. AIFS forecast skill is assessed by comparing its forecasts to NWP analyses and direct observational data.

  • Developed by: ECMWF
  • Model type: Encoder-processor-decoder model
  • License: These model weights are published under a Creative Commons Attribution 4.0 International (CC BY 4.0). To view a copy of this licence, visit https://creativecommons.org/licenses/by/4.0/

Model Sources

  • Repository: Anemoi is an open-source framework for creating machine learning (ML) weather forecasting systems, which ECMWF and a range of national meteorological services across Europe have co-developed.
  • Paper: https://arxiv.org/pdf/2406.01465

How to Get Started with the Model

To generate a new forecast using AIFS, you can use anemoi-inference. In the following notebook, a step-by-step workflow is specified to run the AIFS using the HuggingFace model:

  1. Install Required Packages and Imports
  2. Retrieve Initial Conditions from ECMWF Open Data
  • Select a date
  • Get the data from the ECMWF Open Data API
  • Get input fields
  • Add the single levels fields and pressure levels fields
  • Convert geopotential height into geopotential
  • Create the initial state
  1. Load the Model and Run the Forecast
  • Download the Model's Checkpoint from Hugging Face
  • Create a runner
  • Run the forecast using anemoi-inference
  1. Inspect the generated forecast
  • Plot a field

🚨 Note we train AIFS using flash_attention (https://github.com/Dao-AILab/flash-attention). The use of 'Flash Attention' package also imposes certain requirements in terms of software and hardware. Those can be found under #Installation and Features in https://github.com/Dao-AILab/flash-attention

🚨 Note the aifs_single_v0.2.1.ckpt checkpoint just contains the model’s weights. That file does not contain any information about the optimizer states, lr-scheduler states, etc.

Training Details

Training Data

AIFS is trained to produce 6-hour forecasts. It receives as input a representation of the atmospheric states at t6ht_{−6h}, t0t_{0}, and then forecasts the state at time t+6ht_{+6h}.

AIFS 2m Temperature

The full list of input and output fields is shown below:

Field Level type Input/Output
Geopotential, horizontal and vertical wind components, specific humidity, temperature Pressure level: 50,100, 150, 200, 250,300, 400, 500, 600,700, 850, 925, 1000 Both
Surface pressure, mean sea-level pressure, skin temperature, 2 m temperature, 2 m dewpoint temperature, 10 m horizontal wind components, total column water Surface Both
Total precipitation, convective precipitation Surface Output
Land-sea mask, orography, standard deviation of sub-grid orography, slope of sub-scale orography, insolation, latitude/longitude, time of day/day of year Surface Input

Input and output states are normalised to unit variance and zero mean for each level. Some of the forcing variables, like orography, are min-max normalised.

Training Procedure

  • Pre-training: It was performed on ERA5 for the years 1979 to 2020 with a cosine learning rate (LR) schedule and a total of 260,000 steps. The LR is increased from 0 to 10410^{-4} during the first 1000 steps, then it is annealed to a minimum of 3×1073 × 10^{-7}.
  • Fine-tuning I: The pre-training is then followed by rollout on ERA5 for the years 1979 to 2018, this time with a LR of 6×1076 × 10^{-7}. As in [Lam et al. [2023]](doi: 10.21957/slk503fs2i) we increase the rollout every 1000 training steps up to a maximum of 72 h (12 auto-regressive steps).
  • Fine-tuning II: Finally, to further improve forecast performance, we fine-tune the model on operational real-time IFS NWP analyses. This is done via another round of rollout training, this time using IFS operational analysis data from 2019 and 2020

Training Hyperparameters

  • Optimizer: We use AdamW (Loshchilov and Hutter [2019]) with the ββ-coefficients set to 0.9 and 0.95.

  • Loss function: The loss function is an area-weighted mean squared error (MSE) between the target atmospheric state and prediction.

  • Loss scaling: A loss scaling is applied for each output variable. The scaling was chosen empirically such that all prognostic variables have roughly equal contributions to the loss, with the exception of the vertical velocities, for which the weight was reduced. The loss weights also decrease linearly with height, which means that levels in the upper atmosphere (e.g., 50 hPa) contribute relatively little to the total loss value.

Speeds, Sizes, Times

Data parallelism is used for training, with a batch size of 16. One model instance is split across four 40GB A100 GPUs within one node. Training is done using mixed precision (Micikevicius et al. [2018]), and the entire process takes about one week, with 64 GPUs in total. The checkpoint size is 1.19 GB and as mentioned above, it does not include the optimizer state.

Evaluation

AIFS is evaluated against ECMWF IFS (Integrated Forecast System) for 2022. The results of such evaluation are summarized in the scorecard below that compares different forecast skill measures across a range of variables. For verification, each system is compared against the operational ECMWF analysis from which the forecasts are initialised. In addition, the forecasts are compared against radiosonde observations of geopotential, temperature and windspeed, and SYNOP observations of 2 m temperature, 10 m wind and 24 h total precipitation. The definition of the metrics, such as ACC (ccaf), RMSE (rmsef) and forecast activity (standard deviation of forecast anomaly, sdaf) can be found in e.g Ben Bouallegue et al. ` [2024].

Scorecard comparing forecast scores of AIFS versus IFS (2022)

Forecasts are initialised on 00 and 12 UTC. The scorecard show relative score changes as function of lead time (day 1 to 10) for northern extra-tropics (n.hem), southern extra-tropics (s.hem), tropics and Europe. Blue colours mark score improvements and red colours score degradations. Purple colours indicate an increased in standard deviation of forecast anomaly, while green colours indicate a reduction. Framed rectangles indicate 95% significance level. Variables are geopotential (z), temperature (t), wind speed (ff), mean sea level pressure (msl), 2 m temperature (2t), 10 m wind speed (10ff) and 24 hr total precipitation (tp). Numbers behind variable abbreviations indicate variables on pressure levels (e.g., 500 hPa), and suffix indicates verification against IFS NWP analyses (an) or radiosonde and SYNOP observations (ob). Scores shown are anomaly correlation (ccaf), SEEPS (seeps, for precipitation), RMSE (rmsef) and standard deviation of forecast anomaly (sdaf, see text for more explanation).

Additional evaluation analysis including tropycal cyclone performance or comparison against other popular data-driven models can be found in AIFS preprint (https://arxiv.org/pdf/2406.01465v1) section 4.

Known limitations

  • This version of AIFS shares certain limitations with some of the other data-driven weather forecast models that are trained with a weighted MSE loss, such as blurring of the forecast fields at longer lead times.
  • AIFS exhibits reduced forecast skill in the stratosphere forecast owing to the linear loss scaling with height
  • AIFS currently provides reduced intensity of some high-impact systems such as tropical cyclones.

Technical Specifications

Hardware

We acknowledge PRACE for awarding us access to Leonardo, CINECA, Italy. In particular, this version of the AIFS has been trained on 64 A100 GPUs (40GB).

Software

The model was developed and trained using the AnemoI framework. AnemoI is a framework for developing machine learning weather forecasting models. It comprises of components or packages for preparing training datasets, conducting ML model training and a registry for datasets and trained models. AnemoI provides tools for operational inference, including interfacing to verification software. As a framework it seeks to handle many of the complexities that meteorological organisations will share, allowing them to easily train models from existing recipes but with their own data.

Citation

If you use this model in your work, please cite it as follows:

BibTeX:

@article{lang2024aifs,
  title={AIFS-ECMWF's data-driven forecasting system},
  author={Lang, Simon and Alexe, Mihai and Chantry, Matthew and Dramsch, Jesper and Pinault, Florian and Raoult, Baudouin and Clare, Mariana CA and Lessig, Christian and Maier-Gerber, Michael and Magnusson, Linus and others},
  journal={arXiv preprint arXiv:2406.01465},
  year={2024}
}

APA:

Lang, S., Alexe, M., Chantry, M., Dramsch, J., Pinault, F., Raoult, B., ... & Rabier, F. (2024). AIFS-ECMWF's data-driven forecasting system. arXiv preprint arXiv:2406.01465.

More Information

Find the paper here

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