Landslide initiation thresholds in data-sparse regions: application to landslide early warning criteria in Sitka, Alaska, USA

IF 4.2 2区 地球科学 Q1 GEOSCIENCES, MULTIDISCIPLINARY Natural Hazards and Earth System Sciences Pub Date : 2023-10-18 DOI:10.5194/nhess-23-3261-2023
Annette I. Patton, Lisa V. Luna, Joshua J. Roering, Aaron Jacobs, Oliver Korup, Benjamin B. Mirus
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Abstract

Abstract. Probabilistic models to inform landslide early warning systems often rely on rainfall totals observed during past events with landslides. However, these models are generally developed for broad regions using large catalogs, with dozens, hundreds, or even thousands of landslide occurrences. This study evaluates strategies for training landslide forecasting models with a scanty record of landslide-triggering events, which is a typical limitation in remote, sparsely populated regions. We evaluate 136 statistical models trained on a precipitation dataset with five landslide-triggering precipitation events recorded near Sitka, Alaska, USA, as well as > 6000 d of non-triggering rainfall (2002–2020). We also conduct extensive statistical evaluation for three primary purposes: (1) to select the best-fitting models, (2) to evaluate performance of the preferred models, and (3) to select and evaluate warning thresholds. We use Akaike, Bayesian, and leave-one-out information criteria to compare the 136 models, which are trained on different cumulative precipitation variables at time intervals ranging from 1 h to 2 weeks, using both frequentist and Bayesian methods to estimate the daily probability and intensity of potential landslide occurrence (logistic regression and Poisson regression). We evaluate the best-fit models using leave-one-out validation as well as by testing a subset of the data. Despite this sparse landslide inventory, we find that probabilistic models can effectively distinguish days with landslides from days without slide activity. Our statistical analyses show that 3 h precipitation totals are the best predictor of elevated landslide hazard, and adding antecedent precipitation (days to weeks) did not improve model performance. This relatively short timescale of precipitation combined with the limited role of antecedent conditions likely reflects the rapid draining of porous colluvial soils on the very steep hillslopes around Sitka. Although frequentist and Bayesian inferences produce similar estimates of landslide hazard, they do have different implications for use and interpretation: frequentist models are familiar and easy to implement, but Bayesian models capture the rare-events problem more explicitly and allow for better understanding of parameter uncertainty given the available data. We use the resulting estimates of daily landslide probability to establish two decision boundaries that define three levels of warning. With these decision boundaries, the frequentist logistic regression model incorporates National Weather Service quantitative precipitation forecasts into a real-time landslide early warning “dashboard” system (https://sitkalandslide.org/, last access: 9 October 2023). This dashboard provides accessible and data-driven situational awareness for community members and emergency managers.
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数据稀疏地区的滑坡起始阈值:在美国阿拉斯加州锡特卡滑坡预警准则中的应用
摘要为滑坡早期预警系统提供信息的概率模型通常依赖于在过去滑坡事件中观测到的总降雨量。然而,这些模型通常是为广泛的地区开发的,使用大型目录,有几十个,数百个,甚至数千个滑坡事件。本研究评估了缺乏滑坡触发事件记录的滑坡预测模型的训练策略,这在偏远、人口稀少的地区是一个典型的限制。我们评估了136个统计模型,这些模型是在一个降水数据集上训练的,该数据集包含美国阿拉斯加州锡特卡附近记录的5次引发山体滑坡的降水事件,以及>6000 d非触发性降雨(2002-2020)。我们还进行了广泛的统计评估,主要有三个目的:(1)选择最佳拟合模型,(2)评估首选模型的性能,(3)选择和评估预警阈值。我们使用Akaike、贝叶斯和留一信息标准来比较136个模型,这些模型是在1小时到2周的时间间隔内根据不同的累积降水变量进行训练的,使用频率论和贝叶斯方法来估计潜在滑坡发生的每日概率和强度(逻辑回归和泊松回归)。我们使用留一验证以及通过测试数据子集来评估最佳拟合模型。尽管滑坡数量稀少,但我们发现概率模型可以有效地区分有滑坡的日子和没有滑坡活动的日子。我们的统计分析表明,3小时的降水总量是滑坡危险性升高的最佳预测因子,并且增加之前的降水(天到周)并没有改善模型的性能。这种相对较短的降水时间加上之前条件的有限作用,可能反映了锡特卡周围非常陡峭的山坡上多孔崩积土的快速排水。尽管频率论和贝叶斯推理对滑坡危害产生了相似的估计,但它们在使用和解释方面确实有不同的含义:频率论模型是熟悉的,易于实现,但贝叶斯模型更明确地捕获了罕见事件问题,并允许在给定可用数据的情况下更好地理解参数不确定性。我们使用每日滑坡概率的估计结果来建立两个决策边界,定义三个级别的预警。通过这些决策边界,频率逻辑回归模型将国家气象局定量降水预报纳入实时滑坡预警“仪表板”系统(https://sitkalandslide.org/,最后访问时间:2023年10月9日)。该仪表板为社区成员和应急管理人员提供了可访问的数据驱动的态势感知。
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来源期刊
Natural Hazards and Earth System Sciences
Natural Hazards and Earth System Sciences 地学-地球科学综合
CiteScore
7.60
自引率
6.50%
发文量
192
审稿时长
3.8 months
期刊介绍: Natural Hazards and Earth System Sciences (NHESS) is an interdisciplinary and international journal dedicated to the public discussion and open-access publication of high-quality studies and original research on natural hazards and their consequences. Embracing a holistic Earth system science approach, NHESS serves a wide and diverse community of research scientists, practitioners, and decision makers concerned with detection of natural hazards, monitoring and modelling, vulnerability and risk assessment, and the design and implementation of mitigation and adaptation strategies, including economical, societal, and educational aspects.
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