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Early detection of convective clouds is vital for minimizing hazardous impacts. Forecasting convective initiation (CI) using current multispectral geostationary meteorological satellites is often challenged by high false-alarm rates and missed detections caused by limited resolution. In contrast, high-resolution Earth observation satellites offer more detailed texture information, improving early detection capabilities. We propose a novel methodology that integrates the advanced features of China's latest-generation satellites, Gaofen-4 (GF-4) and Fengyun-4A (FY-4A). This fusion method retains GF's high-resolution details and FY-4A's multispectral information. Two cases from different observational scenarios and weather conditions under GF-4's staring mode were carried out to compare the CI forecast results based on fused data and solely on FY-4A data. The fused data demonstrated superior performance in detecting smaller-scale convective clouds, enabling earlier forecasting with a lead time of 15–30 minutes, and more accurate location identification. Integrating high-resolution earth observation satellites into early convective cloud detection provides valuable insights for forecasters and decision-makers, particularly given the current resolution limitations of geostationary meteorological satellites. 对流云的早期探测对于降低天气致灾风险至关重要.当前静止气象卫星受其分辨率的限制, 在预测对流初生 (CI) 时仍存在较高的虚警率和漏报率.对比而言, 高分辨率的地球观测卫星能够提供更丰富的纹理细节, 有助于提升对流云早期探测的能力.我们提出了一种创新性的方法, 融合GF-4的高分辨率细节和FY-4A的多光谱信息, 以优化对流云的早期识别和预测.通过对GF-4凝视模式下两种不同天气条件和观测场景的案例分析, 融合数据在探测更小尺度的对流云方面具有明显优势, 一定程度解决漏报难题, 另一方面能够将对流初生的可探测时间提前, 更精确表现对流爆发位置和更准确刻画对流发展过程.在当前静止气象卫星分辨率受限的条件下, 这种高分辨率地球观测卫星数据的融合应用能够为气象预报员和决策者提供更有价值的观测视角.
Gao et al. (Sun,) studied this question.