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FuXi-Ocean: A Global Ocean Forecasting System with Sub-Daily Resolution

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📄 Abstract

Abstract: Accurate, high-resolution ocean forecasting is crucial for maritime operations and environmental monitoring. While traditional numerical models are capable of producing sub-daily, eddy-resolving forecasts, they are computationally intensive and face challenges in maintaining accuracy at fine spatial and temporal scales. In contrast, recent data-driven approaches offer improved computational efficiency and emerging potential, yet typically operate at daily resolution and struggle with sub-daily predictions due to error accumulation over time. We introduce FuXi-Ocean, the first data-driven global ocean forecasting model achieving six-hourly predictions at eddy-resolving 1/12{\deg} spatial resolution, reaching depths of up to 1500 meters. The model architecture integrates a context-aware feature extraction module with a predictive network employing stacked attention blocks. The core innovation is the Mixture-of-Time (MoT) module, which adaptively integrates predictions from multiple temporal contexts by learning variable-specific reliability , mitigating cumulative errors in sequential forecasting. Through comprehensive experimental evaluation, FuXi-Ocean demonstrates superior skill in predicting key variables, including temperature, salinity, and currents, across multiple depths.

Authors (8)

Qiusheng Huang

Yuan Niu

Xiaohui Zhong

Anboyu Guo

Lei Chen

Dianjun Zhang

+2 more

Submitted

June 3, 2025

arXiv Category

cs.LG

arXiv PDF

Key Contributions

FuXi-Ocean is the first data-driven global ocean forecasting model capable of providing six-hourly predictions at eddy-resolving 1/12° spatial resolution down to 1500m depth. It integrates a context-aware feature extraction module with a predictive network using stacked attention blocks and a novel Mixture-of-Time (MoT) module for adaptive prediction integration, overcoming limitations of traditional numerical models and existing data-driven approaches.

Business Value

Enables more precise maritime operations (shipping, fishing), better environmental monitoring (pollution tracking, disaster preparedness), and improved climate research, leading to economic benefits and enhanced safety.

Paper Metadata

Innovation Type

Methodology

Deployment Feasibility

Moderate, requires significant computational resources for training and inference, and validation against real-world oceanographic data.

Limitations Addressed

Traditional numerical models are computationally intensive and struggle with fine scales. Existing data-driven approaches typically operate at daily resolution and have issues with sub-daily predictions due to error accumulation. FuXi-Ocean addresses both by offering high-resolution, sub-daily forecasts with improved efficiency.

Performance Gains

Achieves six-hourly predictions at eddy-resolving 1/12° resolution, a significant improvement over existing daily resolution data-driven models.

Technical Tags

Ocean ForecastingHigh-ResolutionEddy-ResolvingData-DrivenSub-Daily ResolutionAttention BlocksMixture-of-Time (MoT)Context-Aware Feature ExtractionNumerical ModelsSpatial Temporal Prediction

Research Topics

OceanographyClimate ModelingData-Driven ForecastingDeep Learning for Scientific SimulationHigh-Resolution Modeling

Methods & Architectures

Context-Aware Feature ExtractionStacked Attention BlocksMixture-of-Time (MoT) ModuleData-Driven Prediction Deep Learning Model (specific architecture not fully detailed but includes attention blocks and MoT)

Applications & Tasks

Oceanography Maritime Operations Environmental Monitoring Climate Science Accurate high-resolution ocean forecastingAchieving sub-daily prediction accuracyOvercoming computational intensity of numerical models Global ocean forecasting at 1/12 deg resolutionPredicting ocean dynamics with six-hour resolutionForecasting ocean conditions up to 1500m depth

Related Fields

OceanographyClimate ScienceDeep LearningScientific ComputingTime Series ForecastingGeophysics

Keywords

Ocean ForecastingHigh ResolutionSub-DailyData-DrivenDeep LearningAttentionMixture-of-TimeEddy ResolvingClimate ModelingMaritimeEnvironmental MonitoringScientific Simulation

Academic Context

#Oceanography#Climate Modeling#Data-Driven Forecasting#Deep Learning for Scientific Simulation#High-Resolution Modeling

Commercial Potential

Potential Products

Real-time ocean condition monitoring servicesHigh-resolution climate simulation toolsMaritime route optimization software

Target Industries

Maritime ShippingOffshore EnergyFisheriesEnvironmental ConsultingClimate Research

Use Case Examples

Predicting wave heights and currents for safe shipping routesForecasting oceanographic conditions for offshore wind farm operationsMonitoring and predicting the spread of marine pollution

Competitive Edge

Represents a significant advancement in data-driven ocean forecasting, achieving unprecedented resolution and temporal frequency compared to previous methods.

Market Opportunity

Global maritime trade volume,Offshore energy market growth,Demand for climate data

Revenue Models

Subscription services for forecast dataConsulting services for maritime and environmental applications

Resource Requirements

Compute Needs

Very High (for training and running global, high-resolution models)

Data Requirements

Extensive historical oceanographic data (temperature, salinity, currents, etc.).

Deployment Constraints

Requires substantial computational infrastructure and access to real-time observational data.

Scalability

Scalability is a key challenge due to the high resolution and global coverage.

Production Readiness

Maturity Level

Research

Time to Market

5-10 years

Patent Potential

Low

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