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Main Authors: Niu, Peisong, Zhang, Haifan, Zhao, Yang, Zhou, Tian, Ma, Ziqing, Shen, Wenqiang, Zhao, Junping, Yuan, Huiling, Sun, Liang
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2603.22314
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author Niu, Peisong
Zhang, Haifan
Zhao, Yang
Zhou, Tian
Ma, Ziqing
Shen, Wenqiang
Zhao, Junping
Yuan, Huiling
Sun, Liang
author_facet Niu, Peisong
Zhang, Haifan
Zhao, Yang
Zhou, Tian
Ma, Ziqing
Shen, Wenqiang
Zhao, Junping
Yuan, Huiling
Sun, Liang
contents Tropical cyclones (TCs) pose severe threats to life, infrastructure, and economies in tropical and subtropical regions, underscoring the critical need for accurate and timely forecasts of both track and intensity. Recent advances in AI-based weather forecasting have shown promise in improving TC track forecasts. However, these systems are typically trained on coarse-resolution reanalysis data (e.g., ERA5 at 0.25 degree), which constrains predicted TC positions to a fixed grid and introduces significant discretization errors. Moreover, intensity forecasting remains limited especially for strong TCs by the smoothing effect of coarse meteorological fields and the use of regression losses that bias predictions toward conditional means. To address these limitations, we propose BaguanCyclone, a novel, unified framework that integrates two key innovations: (1) a probabilistic center refinement module that models the continuous spatial distribution of TC centers, enabling finer track precision; and (2) a region-aware intensity forecasting module that leverages high-resolution internal representations within dynamically defined sub-grid zones around the TC core to better capture localized extremes. Evaluated on the global IBTrACS dataset across six major TC basins, our system consistently outperforms both operational numerical weather prediction (NWP) models and most AI-based baselines, delivering a substantial enhancement in forecast accuracy. Remarkably, BaguanCyclone excels in navigating meteorological complexities, consistently delivering accurate forecasts for re-intensification, sweeping arcs, twin cyclones, and meandering events. Our code is available at https://github.com/DAMO-DI-ML/Baguan-cyclone.
format Preprint
id arxiv_https___arxiv_org_abs_2603_22314
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Enhancing AI-Based Tropical Cyclone Track and Intensity Forecasting via Systematic Bias Correction
Niu, Peisong
Zhang, Haifan
Zhao, Yang
Zhou, Tian
Ma, Ziqing
Shen, Wenqiang
Zhao, Junping
Yuan, Huiling
Sun, Liang
Machine Learning
Artificial Intelligence
Tropical cyclones (TCs) pose severe threats to life, infrastructure, and economies in tropical and subtropical regions, underscoring the critical need for accurate and timely forecasts of both track and intensity. Recent advances in AI-based weather forecasting have shown promise in improving TC track forecasts. However, these systems are typically trained on coarse-resolution reanalysis data (e.g., ERA5 at 0.25 degree), which constrains predicted TC positions to a fixed grid and introduces significant discretization errors. Moreover, intensity forecasting remains limited especially for strong TCs by the smoothing effect of coarse meteorological fields and the use of regression losses that bias predictions toward conditional means. To address these limitations, we propose BaguanCyclone, a novel, unified framework that integrates two key innovations: (1) a probabilistic center refinement module that models the continuous spatial distribution of TC centers, enabling finer track precision; and (2) a region-aware intensity forecasting module that leverages high-resolution internal representations within dynamically defined sub-grid zones around the TC core to better capture localized extremes. Evaluated on the global IBTrACS dataset across six major TC basins, our system consistently outperforms both operational numerical weather prediction (NWP) models and most AI-based baselines, delivering a substantial enhancement in forecast accuracy. Remarkably, BaguanCyclone excels in navigating meteorological complexities, consistently delivering accurate forecasts for re-intensification, sweeping arcs, twin cyclones, and meandering events. Our code is available at https://github.com/DAMO-DI-ML/Baguan-cyclone.
title Enhancing AI-Based Tropical Cyclone Track and Intensity Forecasting via Systematic Bias Correction
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2603.22314