PACER: Physics Informed Uncertainty Aware Climate Emulator
- URL: http://arxiv.org/abs/2410.21657v2
- Date: Wed, 30 Oct 2024 05:33:12 GMT
- Title: PACER: Physics Informed Uncertainty Aware Climate Emulator
- Authors: Hira Saleem, Flora Salim, Cormac Purcell,
- Abstract summary: PACER emulates temperature and precipitation stably for 86 years while only being trained on greenhouse gas emissions data.
We incorporate a fundamental physical law of advection-diffusion in PACER accounting for boundary conditions.
PACER has been trained on 15 climate models provided by ClimateSet outperforming baselines across most of the climate models.
- Score: 0.0
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Climate models serve as critical tools for evaluating the effects of climate change and projecting future climate scenarios. However, the reliance on numerical simulations of physical equations renders them computationally intensive and inefficient. While deep learning methodologies have made significant progress in weather forecasting, they are still unstable for climate emulation tasks. Here, we propose PACER, a lightweight 684K parameter Physics Informed Uncertainty Aware Climate Emulator. PACER emulates temperature and precipitation stably for 86 years while only being trained on greenhouse gas emissions data. We incorporate a fundamental physical law of advection-diffusion in PACER accounting for boundary conditions and empirically estimating the diffusion co-efficient and flow velocities from emissions data. PACER has been trained on 15 climate models provided by ClimateSet outperforming baselines across most of the climate models and advancing a new state of the art in a climate diagnostic task.
Related papers
- Constructing Extreme Heatwave Storylines with Differentiable Climate Models [49.1574468325115]
We present a novel framework that leverages a differentiable hybrid climate model, NeuralGCM, to optimize initial conditions and generate physically consistent worst-case heatwave trajectories.<n>Applying to the 2021 Pacific Northwest heatwave, our method produces heatwave intensity up to 3.7 $circ$C above the most extreme member of a 75-member ensemble.<n>Our results demonstrate that differentiable climate models can efficiently explore the upper tails of event likelihoods, providing a powerful new approach for constructing targeted storylines of extreme weather under climate change.
arXiv Detail & Related papers (2025-06-12T12:50:38Z) - Advancing Seasonal Prediction of Tropical Cyclone Activity with a Hybrid AI-Physics Climate Model [2.5701544858386396]
Machine learning models are successful with weather forecasting and have shown progress in climate simulations.<n>We show this feasibility using Neural General Circulation Model (NeuralGCM), a hybrid ML-physics atmospheric model developed by Google.
arXiv Detail & Related papers (2025-04-30T19:42:16Z) - ClimateBench-M: A Multi-Modal Climate Data Benchmark with a Simple Generative Method [61.76389719956301]
We contribute a multi-modal climate benchmark, i.e., ClimateBench-M, which aligns time series climate data from ERA5, extreme weather events data from NOAA, and satellite image data from NASA.
Under each data modality, we also propose a simple but strong generative method that could produce competitive performance in weather forecasting, thunderstorm alerts, and crop segmentation tasks.
arXiv Detail & Related papers (2025-04-10T02:22:23Z) - Learning to generate physical ocean states: Towards hybrid climate modeling [1.5845117761091052]
Ocean General Circulation Models require extensive computational resources to reach equilibrium states.
Deep learning emulators, despite offering fast predictions, lack the physical interpretability and long-term stability necessary for climate scientists.
We propose to take the best from both worlds by leveraging deep generative models to produce physically consistent oceanic states.
arXiv Detail & Related papers (2025-02-04T17:14:41Z) - Regional climate risk assessment from climate models using probabilistic machine learning [12.737495484442443]
GenFocal is a general-purpose, end-to-end generative framework for complex climate processes interacting at finetemporal scales.<n>It more accurately assesses extreme risk in the current climate than leading approaches.<n>GenFocal shows compelling results consistent with the literature on projecting climate impact on decadal timescales.
arXiv Detail & Related papers (2024-12-11T03:52:17Z) - Efficient Localized Adaptation of Neural Weather Forecasting: A Case Study in the MENA Region [62.09891513612252]
We focus on limited-area modeling and train our model specifically for localized region-level downstream tasks.
We consider the MENA region due to its unique climatic challenges, where accurate localized weather forecasting is crucial for managing water resources, agriculture and mitigating the impacts of extreme weather events.
Our study aims to validate the effectiveness of integrating parameter-efficient fine-tuning (PEFT) methodologies, specifically Low-Rank Adaptation (LoRA) and its variants, to enhance forecast accuracy, as well as training speed, computational resource utilization, and memory efficiency in weather and climate modeling for specific regions.
arXiv Detail & Related papers (2024-09-11T19:31:56Z) - ClimODE: Climate and Weather Forecasting with Physics-informed Neural ODEs [14.095897879222676]
We present ClimODE, a continuous-time process that implements key principle of statistical mechanics.
ClimODE models precise weather evolution with value-conserving dynamics, learning global weather transport as a neural flow.
Our approach outperforms existing data-driven methods in global, regional forecasting with an order of magnitude smaller parameterization.
arXiv Detail & Related papers (2024-04-15T06:38:21Z) - Comparing Data-Driven and Mechanistic Models for Predicting Phenology in
Deciduous Broadleaf Forests [47.285748922842444]
We train a deep neural network to predict a phenological index from meteorological time series.
We find that this approach outperforms traditional process-based models.
arXiv Detail & Related papers (2024-01-08T15:29:23Z) - Towards Causal Representations of Climate Model Data [18.82507552857727]
This work delves into the potential of causal representation learning, specifically the emphCausal Discovery with Single-parent Decoding (CDSD) method.
Our findings shed light on the challenges, limitations, and promise of using CDSD as a stepping stone towards more interpretable and robust climate model emulation.
arXiv Detail & Related papers (2023-12-05T16:13:34Z) - CMIP X-MOS: Improving Climate Models with Extreme Model Output
Statistics [40.517778024431244]
We introduce Extreme Model Output Statistics (X-MOS) to improve predictions of natural disaster risks.
This approach utilizes deep regression techniques to precisely map CMIP model outputs to real measurements obtained from weather stations.
In contrast to previous research, our study places a strong emphasis on enhancing the estimation of the tails of future climate parameter distributions.
arXiv Detail & Related papers (2023-10-24T13:18:53Z) - ClimaX: A foundation model for weather and climate [51.208269971019504]
ClimaX is a deep learning model for weather and climate science.
It can be pre-trained with a self-supervised learning objective on climate datasets.
It can be fine-tuned to address a breadth of climate and weather tasks.
arXiv Detail & Related papers (2023-01-24T23:19:01Z) - Multi-scale Digital Twin: Developing a fast and physics-informed
surrogate model for groundwater contamination with uncertain climate models [53.44486283038738]
Climate change exacerbates the long-term soil management problem of groundwater contamination.
We develop a physics-informed machine learning surrogate model using U-Net enhanced Fourier Neural Contaminated (PDENO)
In parallel, we develop a convolutional autoencoder combined with climate data to reduce the dimensionality of climatic region similarities across the United States.
arXiv Detail & Related papers (2022-11-20T06:46:35Z) - Spatiotemporal modeling of European paleoclimate using doubly sparse
Gaussian processes [61.31361524229248]
We build on recent scale sparsetemporal GPs to reduce the computational burden.
We successfully employ such a doubly sparse GP to construct a probabilistic model of paleoclimate.
arXiv Detail & Related papers (2022-11-15T14:15:04Z) - Climate-Invariant Machine Learning [0.8831201550856289]
Current climate models require representations of processes that occur at scales smaller than model grid size.
Recent machine learning (ML) algorithms hold promise to improve such process representations, but tend to extrapolate poorly to climate regimes they were not trained on.
We propose a new framework - termed "climate-invariant" ML - incorporating knowledge of climate processes into ML algorithms.
arXiv Detail & Related papers (2021-12-14T07:02:57Z) - Loosely Conditioned Emulation of Global Climate Models With Generative
Adversarial Networks [2.937141232326068]
We train two "loosely conditioned" Generative Adversarial Networks (GANs) that emulate daily precipitation output from a fully coupled Earth system model.
GANs are trained to producetemporal samples: 32 days of precipitation over a 64x128 regular grid discretizing the globe.
Our trained GANs can rapidly generate numerous realizations at a vastly reduced computational expense.
arXiv Detail & Related papers (2021-04-29T02:10:08Z) - DeepClimGAN: A High-Resolution Climate Data Generator [60.59639064716545]
Earth system models (ESMs) are often used to generate future projections of climate change scenarios.
As a compromise, emulators are substantially less expensive but may not have all of the complexity of an ESM.
Here we demonstrate the use of a conditional generative adversarial network (GAN) to act as an ESM emulator.
arXiv Detail & Related papers (2020-11-23T20:13:37Z)
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.