Continuous Ensemble Weather Forecasting with Diffusion models
- URL: http://arxiv.org/abs/2410.05431v1
- Date: Mon, 7 Oct 2024 18:51:23 GMT
- Title: Continuous Ensemble Weather Forecasting with Diffusion models
- Authors: Martin Andrae, Tomas Landelius, Joel Oskarsson, Fredrik Lindsten,
- Abstract summary: Continuous Ensemble Forecasting is a novel and flexible method for sampling ensemble forecasts in diffusion models.
It can generate temporally consistent ensemble trajectories completely in parallel, with no autoregressive steps.
We demonstrate that the method achieves competitive results for global weather forecasting with good probabilistic properties.
- Score: 10.730406954385927
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Weather forecasting has seen a shift in methods from numerical simulations to data-driven systems. While initial research in the area focused on deterministic forecasting, recent works have used diffusion models to produce skillful ensemble forecasts. These models are trained on a single forecasting step and rolled out autoregressively. However, they are computationally expensive and accumulate errors for high temporal resolution due to the many rollout steps. We address these limitations with Continuous Ensemble Forecasting, a novel and flexible method for sampling ensemble forecasts in diffusion models. The method can generate temporally consistent ensemble trajectories completely in parallel, with no autoregressive steps. Continuous Ensemble Forecasting can also be combined with autoregressive rollouts to yield forecasts at an arbitrary fine temporal resolution without sacrificing accuracy. We demonstrate that the method achieves competitive results for global weather forecasting with good probabilistic properties.
Related papers
- Weather Prediction with Diffusion Guided by Realistic Forecast Processes [49.07556359513563]
We introduce a novel method that applies diffusion models (DM) for weather forecasting.
Our method can achieve both direct and iterative forecasting with the same modeling framework.
The flexibility and controllability of our model empowers a more trustworthy DL system for the general weather community.
arXiv Detail & Related papers (2024-02-06T21:28:42Z) - ExtremeCast: Boosting Extreme Value Prediction for Global Weather Forecast [57.6987191099507]
We introduce Exloss, a novel loss function that performs asymmetric optimization and highlights extreme values to obtain accurate extreme weather forecast.
We also introduce ExBooster, which captures the uncertainty in prediction outcomes by employing multiple random samples.
Our solution can achieve state-of-the-art performance in extreme weather prediction, while maintaining the overall forecast accuracy comparable to the top medium-range forecast models.
arXiv Detail & Related papers (2024-02-02T10:34:13Z) - Fine-grained Forecasting Models Via Gaussian Process Blurring Effect [6.472434306724611]
Time series forecasting is a challenging task due to the existence of complex and dynamic temporal dependencies.
Using more training data is one way to improve the accuracy, but this source is often limited.
We are building on successful denoising approaches for image generation by advocating for an end-to-end forecasting and denoising paradigm.
arXiv Detail & Related papers (2023-12-21T20:25:16Z) - When Rigidity Hurts: Soft Consistency Regularization for Probabilistic
Hierarchical Time Series Forecasting [69.30930115236228]
Probabilistic hierarchical time-series forecasting is an important variant of time-series forecasting.
Most methods focus on point predictions and do not provide well-calibrated probabilistic forecasts distributions.
We propose PROFHiT, a fully probabilistic hierarchical forecasting model that jointly models forecast distribution of entire hierarchy.
arXiv Detail & Related papers (2023-10-17T20:30:16Z) - SEEDS: Emulation of Weather Forecast Ensembles with Diffusion Models [13.331224394143117]
Uncertainty quantification is crucial to decision-making.
dominant approach to representing uncertainty in weather forecasting is to generate an ensemble of forecasts.
We propose to amortize the computational cost by emulating these forecasts with deep generative diffusion models learned from historical data.
arXiv Detail & Related papers (2023-06-24T22:00:06Z) - When Rigidity Hurts: Soft Consistency Regularization for Probabilistic
Hierarchical Time Series Forecasting [69.30930115236228]
Probabilistic hierarchical time-series forecasting is an important variant of time-series forecasting.
Most methods focus on point predictions and do not provide well-calibrated probabilistic forecasts distributions.
We propose PROFHiT, a fully probabilistic hierarchical forecasting model that jointly models forecast distribution of entire hierarchy.
arXiv Detail & Related papers (2022-06-16T06:13:53Z) - Distributional Gradient Boosting Machines [77.34726150561087]
Our framework is based on XGBoost and LightGBM.
We show that our framework achieves state-of-the-art forecast accuracy.
arXiv Detail & Related papers (2022-04-02T06:32:19Z) - Learning Interpretable Deep State Space Model for Probabilistic Time
Series Forecasting [98.57851612518758]
Probabilistic time series forecasting involves estimating the distribution of future based on its history.
We propose a deep state space model for probabilistic time series forecasting whereby the non-linear emission model and transition model are parameterized by networks.
We show in experiments that our model produces accurate and sharp probabilistic forecasts.
arXiv Detail & Related papers (2021-01-31T06:49:33Z) - Deep Learning for Post-Processing Ensemble Weather Forecasts [14.622977874836298]
We propose a mixed model that uses only a subset of the original weather trajectories combined with a post-processing step using deep neural networks.
We show that our post-processing can use fewer trajectories to achieve comparable results to the full ensemble.
arXiv Detail & Related papers (2020-05-18T14:23:26Z) - A framework for probabilistic weather forecast post-processing across
models and lead times using machine learning [3.1542695050861544]
We show how to bridge the gap between sets of separate forecasts from NWP models and the 'ideal' forecast for decision support.
We use Quantile Regression Forests to learn the error profile of each numerical model, and use these to apply empirically-derived probability distributions to forecasts.
Second, we combine these probabilistic forecasts using quantile averaging. Third, we interpolate between the aggregate quantiles in order to generate a full predictive distribution.
arXiv Detail & Related papers (2020-05-06T16:46:02Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.