Comparison and validation of global and regional ocean forecasting systems
for the South China Sea

Zhu, Xiaodong; Wang, Hui; Liu, Guimei; Régnier, Charly; Wang, Dakui; Ren, Shihe; Jing, Zhiyou; Drévillon, Marie

doi:10.5194/nhess-16-1639-2016

Cited by 15 publications

(23 citation statements)

References 59 publications

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“…As mentioned in the literature of Zhu et al (2016), the regional SCS Operational Oceanography 85Forecasting System (SCSOFS, here after named it as SCSOFSv1) has been developed and routinely operated in real time since the beginning of 2013. It has continued to be upgraded by modifying model settings in many aspects, such as mesh distributions, surface atmospheric field forcing, open boundary inputs, and so on, and improving data assimilation scheme according to the results of comparing and validating from Zhu et al (2016), in order to provide better services. The primary purpose of this paper 90 is to introducing updates applied to SCSOFS, but only show the highest impact on the system.…”

Section: Within Coordination and Leadership Of Global Ocean Data Assimilation Experiments (Godae)mentioning

confidence: 99%

The improvements to the regional South China Sea Operational Oceanography Forecasting System (SCSOFSv1)

Zhu

Ren

et al. 2021

Preprint

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Abstract. South China Sea Operational Oceanography Forecasting System (SCSOFS) had been constructed and operated in National Marine Environmental Forecasting Center of China to provide daily updated hydrodynamic forecasting in SCS for the future 5 days since 2013. This paper presents recent comprehensive updates of the configurations of the physical model and data assimilation scheme in order to improve SCSOFS forecasting skills. It highlights three of the most sensitive updates, including sea surface atmospheric forcing method, tracers advection discrete scheme, and modification of data assimilation scheme. Inter-comparison and accuracy assessment among five versions during the whole upgrading processes are performed by employing OceanPredict Inter-comparison and Validation Task Team Class4 metrics. The results indicate that remarkable improvements have been achieved in SCSOFSv2 with respect to the original version known as SCSOFSv1. Domain averaged monthly mean root mean square errors decrease from 1.21 °C to 0.52 °C for sea surface temperature, from 21.6 cm to 8.5 cm for sea level anomaly, respectively.

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Section: Within Coordination and Leadership Of Global Ocean Data Assimilation Experiments (Godae)mentioning

confidence: 99%

The improvements to the regional South China Sea Operational Oceanography Forecasting System (SCSOFSv1)

Zhu

Ren

et al. 2021

Preprint

Self Cite

View full text Add to dashboard Cite

show abstract

“…As mentioned in the literature of Zhu et al (2016), the regional SCS Operational Oceanography Forecasting System (SCSOFS, here after named it as SCSOFSv1) has been developed and routinely 85 operated in real time since the beginning of 2013. It has continued to be upgraded by modifying model settings in many aspects, such as mesh distributions, surface atmospheric field forcing, open boundary inputs, and so on, and improving data assimilation scheme according to the results of comparing and validating from Zhu et al (2016), in order to provide better services. The primary purpose of this paper is to introducing updates applied to SCSOFS, but only show the highest impact on the system.…”

Section: Within Coordination and Leadership Of Global Ocean Data Assimilation Experiments (Godae)mentioning

confidence: 99%

“…As mentioned as Zhu et al (2016), the original SCSOFSv1 had employed the multivariate Ensemble Optimal Interpolation (EnOI, Evensen, 2003;Oke et al, 2008) four different variables to one array, respectively.…”

Section: Data Assimilation Scheme 325mentioning

confidence: 99%

“…EnOI data assimilation scheme in recent couple years based on the recommendations ofZhu et al (2016), such as land-water grid mask redistribution, data sources for bathymetry, initial condition, sea surface forcing and open boundary condition changing to higher horizontal and temporal resolution, moving the eastern lateral boundary westward, increasing vertical layers of model, and so on.…”

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confidence: 99%

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The improvements to the regional South China Sea Operational Oceanography Forecasting System

Zhu

Ren

et al. 2020

Preprint

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Abstract. South China Sea Operational Oceanography Forecasting System (SCSOFS) had been built up and operated in National Marine Environmental Forecasting Center of China to provide daily updated hydrodynamic forecasting in SCS for the future 5 days since 2013. This paper presents comprehensive updates had been conducted to the configurations of the physical model and data assimilation scheme in order to improve SCSOFS forecasting skills in recent years. It highlights three of the most sensitive updates, sea surface atmospheric forcing method, tracers advection discrete scheme, and modification of data assimilation scheme. Scientific inter-comparison and accuracy assessment among five versions during the whole upgrading processes are performed by employing Global Ocean Data Assimilation Experiment OceanView Inter-comparison and Validation Task Team Class4 metrics. The results indicate that remarkable improvements have been achieved in SCSOFSv2 with respect to the original version SCSOFSv1. Domain averaged monthly mean root mean square errors decrease from 1.21 °C to 0.52 °C for sea surface temperature, from 21.6 cm to 8.5 cm for sea level anomaly, respectively.

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“…For example, Ziegeler et al (2012) uses a method that determines the displacement of features relative to a mapped product. Zhu et al (2016) looks at distribution of SST fronts but does not define a quantitative metric for evaluation of their accuracy. However, these methods and metrics are not appropriate for application to altimetric measurements.…”

Section: Introductionmentioning

confidence: 99%

Detection of Fronts as a Metric for Numerical Model Accuracy

Douglass

Mask

2019

Journal of Atmospheric and Oceanic Technology

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As numerical modeling advances, quantitative metrics are necessary to determine whether the model output accurately represents the observed ocean. Here, a metric is developed based on whether a model places oceanic fronts in the proper location. Fronts are observed and assessed directly from along-track satellite altimetry. Numerical model output is then interpolated to the locations of the along-track data, and fronts are detected in the model output. Scores are determined from the percentage of observed fronts correctly simulated in the model and from the percentage of modeled fronts confirmed by observations. These scores depend on certain parameters such as the minimum size of a front, which will be shown to be geographically dependent. An analysis of two models, the Hybrid Coordinate Ocean Model (HYCOM) and the Navy Coastal Ocean Model (NCOM), is presented as an example of how this metric might be applied and interpreted. In this example, scores are found to be relatively stable in time, but strongly dependent on the mesoscale variability in the region of interest. In all cases, the metric indicates that there are more observed fronts not found in the models than there are modeled fronts missing from observations. In addition to the score itself, the analysis demonstrates that modeled fronts have smaller amplitude and are less steep than observed fronts.

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Comparison and validation of global and regional ocean forecasting systems for the South China Sea

Cited by 15 publications

References 59 publications

The improvements to the regional South China Sea Operational Oceanography Forecasting System (SCSOFSv1)

The improvements to the regional South China Sea Operational Oceanography Forecasting System (SCSOFSv1)

The improvements to the regional South China Sea Operational Oceanography Forecasting System

Detection of Fronts as a Metric for Numerical Model Accuracy

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