Related papers: OMG-HD: A High-Resolution AI Weather Model for End-to-End Forecasts from Observations

OMG-HD: A High-Resolution AI Weather Model for End-to-End Forecasts from Observations

URL: http://arxiv.org/abs/2412.18239v1
Date: Tue, 24 Dec 2024 07:46:50 GMT
Title: OMG-HD: A High-Resolution AI Weather Model for End-to-End Forecasts from Observations
Authors: Pengcheng Zhao, Jiang Bian, Zekun Ni, Weixin Jin, Jonathan Weyn, Zuliang Fang, Siqi Xiang, Haiyu Dong, Bin Zhang, Hongyu Sun, Kit Thambiratnam, Qi Zhang,
Abstract summary: OMG-HD is an AI-based high-resolution weather forecasting model designed to make predictions directly from observational data sources. We achieve up to a 13% improvement on RMSE for 2-meter temperature, 17% on 10-meter wind speed, 48% on 2-meter specific humidity, and 32% on surface pressure.
Score: 11.729902584481767
License:
Abstract: In recent years, Artificial Intelligence Weather Prediction (AIWP) models have achieved performance comparable to, or even surpassing, traditional Numerical Weather Prediction (NWP) models by leveraging reanalysis data. However, a less-explored approach involves training AIWP models directly on observational data, enhancing computational efficiency and improving forecast accuracy by reducing the uncertainties introduced through data assimilation processes. In this study, we propose OMG-HD, a novel AI-based regional high-resolution weather forecasting model designed to make predictions directly from observational data sources, including surface stations, radar, and satellite, thereby removing the need for operational data assimilation. Our evaluation shows that OMG-HD outperforms both the European Centre for Medium-Range Weather Forecasts (ECMWF)'s high-resolution operational forecasting system, IFS-HRES, and the High-Resolution Rapid Refresh (HRRR) model at lead times of up to 12 hours across the contiguous United States (CONUS) region. We achieve up to a 13% improvement on RMSE for 2-meter temperature, 17% on 10-meter wind speed, 48% on 2-meter specific humidity, and 32% on surface pressure compared to HRRR. Our method shows that it is possible to use AI-driven approaches for rapid weather predictions without relying on NWP-derived weather fields as model input. This is a promising step towards using observational data directly to make operational forecasts with AIWP models.

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