Analysis of Landslide Triggering Rainfall Threshold for Prediction of Landslide Occurrence

Oh, Jeongrim; Park, Hyuck‐Jin

doi:10.9798/kosham.2014.14.2.115

Cited by 10 publications

(2 citation statements)

References 13 publications

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“…A rainfall event is divided by a nonrainfall period in an objective way to separate the case whether the rainfall event affects the landslide. In general, studies distinguish rainfall events based on a 24-h non-rainfall period (Guzzetti et al 2008;Saito et al 2010;Chen et al 2015;Kim et al 2013;Oh and Park 2014;Hong et al 2016;Kang and Kim 2016;Lee and Kim 2017;Park et al 2018). Brunetti et al (2010) separated rainfall events based on a non-rainfall period to account for different meteorological regimes, 48-h periods without rainfall during the dry and warm season (May-September), and 96-h periods without rainfall during the wet and cold season (October-April).…”

Section: Introductionmentioning

confidence: 99%

The optimal rainfall thresholds and probabilistic rainfall conditions for a landslide early warning system for Chuncheon, Republic of Korea

2021

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The purpose of this study is to establish the criteria for a landslide early warning system (LEWS). We accomplished this by deriving optimal thresholds for the cumulative event rainfall–duration (ED) and identifying the characteristics of the rainfall variables associated with a high probability of landslide occurrence via a Bayesian model. We have established these system criteria using rainfall and landslide data for Chuncheon, Republic of Korea. Heavy rainfall is the leading cause of landslides in Chuncheon; thus, it is crucial to determine the rainfall conditions that trigger landslides. Hourly rainfall data spanning 1999 to 2017 from seven gauging stations were utilized to establish the ED thresholds and the Bayesian model. We used three different calibration periods of rainfall events split by 12, 24, 48, and 96 non-rainfall hours to calibrate the ED thresholds. Finally, the optimal threshold was determined by comparing the results of the contingency table and the skill scores that maximize the probability of detection (POD) score and minimize the probability of false detection (POFD) score. In the LEWS, by considering the first level as “normal,” we developed subsequent step-by-step warning levels based on the Bayesian model as well as the ED thresholds. We propose the second level, “watch,” when the rainfall condition is above the ED thresholds. We then adopt the third level, “warning,” and the fourth level, “severe warning,” based on the probability of landslide occurrence determined via a Bayesian model that considers several factors including the rainfall conditions of landslide vs. non-landslide and various rainfall variables such as hourly maximum rainfall and 3-day antecedent rainfall conditions. The proposed alert level predicted a total of 98.2% of the landslide occurrences at the levels of “severe warning” and “warning” as a result of the model fitness verification. The false alarm rate is 0% for the severe warning level and 47.4% for the warning level. We propose using the optimal ED thresholds to forecast when landslides are likely to occur in the local region. Additionally, we propose the ranges of rainfall variables that represent a high landslide probability based on the Bayesian model to set the landslide warning standard that fits the local area’s characteristics.

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Section: Introductionmentioning

confidence: 99%

The optimal rainfall thresholds and probabilistic rainfall conditions for a landslide early warning system for Chuncheon, Republic of Korea

2021

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“…In terms of the geological conditions of Korea, weathered residual soils in hillslope areas can be represented by poorly or well graded sand according to the Unified Soil Classification System [6,34]. Based on this geological background, numerous previous studies that analyzed the relationship between rainfall characteristics and landslides in Korea set the minimum non-rainfall period as 24 h [35][36][37][38]. In addition, the well-qualified in situ monitoring results of Lee et al [39], which measured matric suction in a natural slope, corroborates the relevance of the period of 24 h as the minimum duration required for the matric suction of a soil to return to its initial state following a sharp decrease due to rainfall infiltration during wet seasons.…”

Section: Definition Of Critical Continuous Rainfallmentioning

confidence: 99%

Critical Continuous Rainfall Map for Forecasting Shallow Landslide Initiations in Busan, Korea

Park

Lee

et al. 2020

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In recent years, precipitation patterns in Korea have shifted to be characterized as short and intense rainfalls. In consideration of shallow landslide initiations primarily governed by heavy rainfalls at short-time scales that diminish drainage effects, the concept of critical continuous rainfall is proposed as a single-rainfall-variable threshold for shallow landslide forecasting. To generate a critical continuous rainfall map for hillslope areas in a city of Korea (Busan), this study designed and applied a systematic modeling process. As a preparatory stage, input datasets of geo-hydraulic properties and geotechnical properties were assembled using estimation techniques based on experiment data of field samples. The inherent and fixed critical continuous rainfall values for hillslope areas in Busan were derived through one-dimensional infiltration analysis coupled with infinite slope stability calculations. As a result of a detailed analysis of historical rainfall records in a case study area over a period of 11 years, three false forecasting cases were recorded, whereas all landslide-triggering rainfall events were correctly captured with no missed forecasting cases. The results of the case study indicate that the proposed critical continuous rainfall may be useful as an effective and straightforward indicator for forecasting the initiation of shallow landslides.

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Temporal prediction modeling for rainfall-induced shallow landslide hazards using extreme value distribution

et al. 2020

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Analysis of Landslide Triggering Rainfall Threshold for Prediction of Landslide Occurrence

Cited by 10 publications

References 13 publications

The optimal rainfall thresholds and probabilistic rainfall conditions for a landslide early warning system for Chuncheon, Republic of Korea

The optimal rainfall thresholds and probabilistic rainfall conditions for a landslide early warning system for Chuncheon, Republic of Korea

Critical Continuous Rainfall Map for Forecasting Shallow Landslide Initiations in Busan, Korea

Temporal prediction modeling for rainfall-induced shallow landslide hazards using extreme value distribution

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