ORCAst: Operational High-Resolution Current Forecasts
- URL: http://arxiv.org/abs/2501.12054v1
- Date: Tue, 21 Jan 2025 11:26:02 GMT
- Title: ORCAst: Operational High-Resolution Current Forecasts
- Authors: Pierre Garcia, Inès Larroche, Amélie Pesnec, Hannah Bull, Théo Archambault, Evangelos Moschos, Alexandre Stegner, Anastase Charantonis, Dominique Béréziat,
- Abstract summary: ORCAst is a multi-stage, multi-arm network for Operational high-Resolution Current forecAsts.<n>Our model learns to forecast global ocean surface currents using various sources of ground truth observations.
- Score: 36.614535202321235
- License: http://creativecommons.org/licenses/by-nc-sa/4.0/
- Abstract: We present ORCAst, a multi-stage, multi-arm network for Operational high-Resolution Current forecAsts over one week. Producing real-time nowcasts and forecasts of ocean surface currents is a challenging problem due to indirect or incomplete information from satellite remote sensing data. Entirely trained on real satellite data and in situ measurements from drifters, our model learns to forecast global ocean surface currents using various sources of ground truth observations in a multi-stage learning procedure. Our multi-arm encoder-decoder model architecture allows us to first predict sea surface height and geostrophic currents from larger quantities of nadir and SWOT altimetry data, before learning to predict ocean surface currents from much more sparse in situ measurements from drifters. Training our model on specific regions improves performance. Our model achieves stronger nowcast and forecast performance in predicting ocean surface currents than various state-of-the-art methods.
Related papers
- OKG-LLM: Aligning Ocean Knowledge Graph with Observation Data via LLMs for Global Sea Surface Temperature Prediction [70.48962924608033]
This work presents the first systematic effort to construct an Ocean Knowledge Graph (OKG) specifically designed to represent diverse ocean knowledge for SST prediction.<n>We develop a graph embedding network to learn the comprehensive semantic and structural knowledge within the OKG, capturing both the unique characteristics of individual sea regions and the complex correlations between them. Finally, we align the learned knowledge with fine-grained numerical SST data and leverage a pre-trained LLM to model SST patterns for accurate prediction.
arXiv Detail & Related papers (2025-07-31T02:06:03Z) - FuXi-Ocean: A Global Ocean Forecasting System with Sub-Daily Resolution [10.627782397713856]
FuXi-Ocean is the first data-driven global ocean forecasting model achieving six-hourly predictions at eddy-resolving 1/12deg spatial resolution.<n>The model architecture integrates a context-aware feature extraction module with a predictive network employing stacked attention blocks.<n>FuXi-Ocean demonstrates superior skill in predicting key variables, including temperature, salinity, and currents, across multiple depths.
arXiv Detail & Related papers (2025-06-03T00:52:31Z) - Deep Learning Weather Models for Subregional Ocean Forecasting: A Case Study on the Canary Current Upwelling System [0.0]
This work aims to adapt a graph neural network initially developed for global weather forecasting to improve subregional ocean prediction.<n>The model is trained with satellite data and compared to state-of-the-art physical ocean models to assess its performance in capturing ocean dynamics.<n>Our results show that the deep learning model surpasses traditional methods in precision despite some challenges in upwelling areas.
arXiv Detail & Related papers (2025-05-30T10:10:40Z) - Multi-Source Temporal Attention Network for Precipitation Nowcasting [4.726419619132143]
Precipitation nowcasting is crucial across various industries and plays a significant role in mitigating and adapting to climate change.<n>We introduce an efficient deep learning model for precipitation nowcasting, capable of predicting rainfall up to 8 hours in advance with greater accuracy than existing operational models.
arXiv Detail & Related papers (2024-10-11T09:09:07Z) - Continual Learning of Range-Dependent Transmission Loss for Underwater Acoustic using Conditional Convolutional Neural Net [0.0]
This research aims to improve the accuracy of deep-learning models for predicting underwater radiated noise in far-field scenarios.
We propose a novel range-conditional convolutional neural network that incorporates ocean bathymetry data into the input.
Our proposed architecture effectively captures transmission loss over a range-dependent, varying bathymetry profile.
arXiv Detail & Related papers (2024-04-11T19:13:38Z) - Learning Robust Precipitation Forecaster by Temporal Frame Interpolation [65.5045412005064]
We develop a robust precipitation forecasting model that demonstrates resilience against spatial-temporal discrepancies.
Our approach has led to significant improvements in forecasting precision, culminating in our model securing textit1st place in the transfer learning leaderboard of the textitWeather4cast'23 competition.
arXiv Detail & Related papers (2023-11-30T08:22:08Z) - Evaluation of Deep Neural Operator Models toward Ocean Forecasting [0.3774866290142281]
Deep neural operator models can predict classic fluid flows and simulations of realistic ocean dynamics.
We first evaluate the capabilities of such deep neural operator models when trained on a simulated two-dimensional fluid flow past a cylinder.
We then investigate their application to forecasting ocean surface circulation in the Middle Atlantic Bight and Massachusetts Bay.
arXiv Detail & Related papers (2023-08-22T22:38:54Z) - Rapid Flood Inundation Forecast Using Fourier Neural Operator [77.30160833875513]
Flood inundation forecast provides critical information for emergency planning before and during flood events.
High-resolution hydrodynamic modeling has become more accessible in recent years, however, predicting flood extents at the street and building levels in real-time is still computationally demanding.
We present a hybrid process-based and data-driven machine learning (ML) approach for flood extent and inundation depth prediction.
arXiv Detail & Related papers (2023-07-29T22:49:50Z) - Machine learning for phase-resolved reconstruction of nonlinear ocean
wave surface elevations from sparse remote sensing data [37.69303106863453]
We propose a novel approach for phase-resolved wave surface reconstruction using neural networks.
Our approach utilizes synthetic yet highly realistic training data on uniform one-dimensional grids.
arXiv Detail & Related papers (2023-05-18T12:30:26Z) - Fully Convolutional Networks for Dense Water Flow Intensity Prediction
in Swedish Catchment Areas [7.324969824727792]
We propose a machine learning-based approach for predicting water flow intensities in inland watercourses.
We are the first to tackle the task of dense water flow intensity prediction.
arXiv Detail & Related papers (2023-04-04T09:28:36Z) - An evaluation of deep learning models for predicting water depth
evolution in urban floods [59.31940764426359]
We compare different deep learning models for prediction of water depth at high spatial resolution.
Deep learning models are trained to reproduce the data simulated by the CADDIES cellular-automata flood model.
Our results show that the deep learning models present in general lower errors compared to the other methods.
arXiv Detail & Related papers (2023-02-20T16:08:54Z) - Data-Driven Short-Term Daily Operational Sea Ice Regional Forecasting [52.77986479871782]
Global warming made the Arctic available for marine operations and created demand for reliable operational sea ice forecasts.
In this work, we investigate the performance of the U-Net model trained in two regimes for predicting sea ice for up to the next 10 days.
We show that this deep learning model can outperform simple baselines by a significant margin and improve its quality by using additional weather data and training on multiple regions.
arXiv Detail & Related papers (2022-10-17T09:14:35Z) - Learning-based estimation of in-situ wind speed from underwater
acoustics [58.293528982012255]
We introduce a deep learning approach for the retrieval of wind speed time series from underwater acoustics.
Our approach bridges data assimilation and learning-based frameworks to benefit both from prior physical knowledge and computational efficiency.
arXiv Detail & Related papers (2022-08-18T15:27:40Z)
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.