Probabilistic short-range forecasts of high precipitation events: optimal decision thresholds and predictability limits

Bouttier, François; Marchal, Hugo

doi:10.5194/egusphere-2023-3111

Cited by 2 publications

(1 citation statement)

References 36 publications

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“…As to rainstorm and flood disasters risk assessment, currently, researchers have primarily focused on three key areas. Firstly, GIS technology and hydrological dynamical models are utilized to construct flood disaster assessment models (Quan, 2014;Wu et al, 2015;Wu et al, 2019;Wang et al, 2022;Bouttier et al, 2024). The models consider factors related to flood risk, exposure and vulnerability of entities susceptible to disasters, and disaster prevention and mitigation capabilities.…”

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Evaluating the disaster risk levels associated with “Dragon Boat Water” in Guangdong China

Hu,

Jiang,

Wang

et al. 2024

Preprint

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Abstract. Dragon Boat Water (DBW) is a period characterized by abundant precipitation and concentrated precipitation process in Guangdong province, China. The period often leads to severe flood disasters, resulting in substantial losses to both livelihoods and production. However, a comprehensive assessment of disaster risk during DBW has been lacking. In this study, we utilized daily precipitation data spanning the years from 1995 to 2020, coupled with related disaster data from Guangdong. The Precipitation Comprehensive Intensity Index (PCII) and the DBW Comprehensive Disaster Index (CDI) were established. PCII and CDI were categorized into three levels using the percentile method. Moreover, we delved into the intricate relationship between these two indexes. The results revealed that PCII falls into the three levels: extreme heavy, heavy, and normal, representing 19.2 %, 30.8 %, and 50 %, respectively, with the peak occurring in 2008. Meanwhile, CDI comprises three levels: high, medium and low, accounting for 19.2 %, 30.8 % and 50.0 %, respectively, with peak years closely aligning with those of PCII. Our calculations demonstrated a positive correlation between PCII and CDI, as well as between PCII and the occurrence of five types of disasters. Notably, heavier PCII levels had a more pronounce impact on crop damage, affected population numbers, and the direct economic loss, with the most substantial influence observed on the affected population. Though disaster data for 2022 has yet to be fully collated, based on PCII and CDI, we determined that 2022 experienced the fourth-highest precipitation and fifth-highest disaster level since 1995. This assessment concurs with the actual conditions observe in 2022. As a result, we propose that in the future, PCII and CDI can be invaluable tools for pre-disaster risk assessment, ongoing disaster monitoring, and expedited post-disaster evaluation.

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confidence: 99%

Evaluating the disaster risk levels associated with “Dragon Boat Water” in Guangdong China

Hu,

Jiang,

Wang

et al. 2024

Preprint

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Probabilistic short-range forecasts of high-precipitation events: optimal decision thresholds and predictability limits

Bouttier,

Marchal

2024

Nat. Hazards Earth Syst. Sci.

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Abstract. Translation of ensemble predictions into high-precipitation warnings is assessed using user-oriented metrics. Short-range probabilistic forecasts are derived from an operational ensemble prediction system using neighbourhood postprocessing and conversion into categorical predictions by decision threshold optimization. Forecast skill is modelled for two different types of users. We investigate the balance between false alarms and missed events and the implications of the scales at which forecast information is communicated. We propose an ensemble-based deterministic forecasting procedure that can be optimized with respect to spatial scale and a frequency ratio between false alarms and missed events. Results show that ensemble predictions objectively outperform the corresponding deterministic control forecasts at low precipitation intensities when an optimal probability threshold is used. The optimal threshold depends on the choice of forecast performance metric, and the superiority of the ensemble prediction over the deterministic control is more apparent at higher precipitation intensities. Thresholds estimated from a short forecast archive are robust with respect to forecast range and season and can be extrapolated for extreme values to estimate severe-weather guidance. Numerical weather forecast value is found to be limited: the highest usable precipitation intensities have return periods of a few years only, with resolution limited to several tens of kilometres. Implied precipitation warnings fall short of common skill requirements for high-impact weather, confirming the importance of human expertise, nowcasting information, and the potential of machine learning approaches. The verification methodology presented here provides a benchmark for high-precipitation forecasts, based on metrics that are relatively easy to compute and explain to non-experts.

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Probabilistic short-range forecasts of high precipitation events: optimal decision thresholds and predictability limits

Cited by 2 publications

References 36 publications

Evaluating the disaster risk levels associated with “Dragon Boat Water” in Guangdong China

Evaluating the disaster risk levels associated with “Dragon Boat Water” in Guangdong China

Probabilistic short-range forecasts of high-precipitation events: optimal decision thresholds and predictability limits

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