Seasonal forecasting has numerous socioeconomic benefits because it can be used for disaster mitigation. Therefore, it is necessary to diagnose and improve the seasonal forecast model. Moreover, the model performance is partly related to the ocean model. This study evaluated the hindcast performance in the upper ocean of the Global Seasonal Forecasting System version 5-Global Couple Configuration 2 (GloSea5-GC2) using a multivariable integrated evaluation method. The normalized potential temperature, salinity, zonal and meridional currents, and sea surface height anomalies were evaluated. Model performance was affected by the target month and was found to be better in the Pacific than in the Atlantic. An increase in lead time led to a decrease in overall model performance, along with decreases in interannual variability, pattern similarity, and root mean square vector deviation. Improving the performance for ocean currents is a more critical than enhancing the performance for other evaluated variables. The tropical Pacific showed the best accuracy in the surface layer, but a spring predictability barrier was present. At the depth of 301 m, the north Pacific and tropical Atlantic exhibited the best and worst accuracies, respectively. These findings provide fundamental evidence for the ocean forecasting performance of GloSea5.

Abstract
Introduction
Model Description andMethodology
    GloSea5
    Multivariable Integrated Evaluation
    Data and Methodology
Results
Summary and Discussion
References

• Hyomee Lee(Division of Science Education & Institute of Fusion Science, Jeonbuk National University)
• Byung-Kwon Moon(Division of Science Education & Institute of Fusion Science, Jeonbuk National University) Corresponding author
• Han-Kyoung Kim(Division of Science Education & Institute of Fusion Science, Jeonbuk National University/Division of Earth and Environmental Science, Jeonbuk National University)
• Jieun Wie(Division of Science Education & Institute of Fusion Science, Jeonbuk National University)
• Hyo Jin Park(Jeonju Jungang Middle School)
• Pil-Hun Chang(Operational Systems Development Department, National Institute of Meteorological Sciences)
• Johan Lee(Operational Systems Development Department, National Institute of Meteorological Sciences)
• Yoonjae Kim(Korean National Meteorological Satellite Center)