TY - JOUR
T1 - Deciphering seasonal effects of triggering and preparatory precipitation for improved shallow landslide prediction using generalized additive mixed models
AU - Steger, Stefan
AU - Moreno, M.
AU - Crespi, Alice
AU - Zellner, Peter James
AU - Gariano, Stefano Luigi
AU - Brunetti, Maria Teresa
AU - Melillo, Massimo
AU - Peruccacci, Silvia
AU - Marra, Francesco
AU - Kohrs, Robin
AU - Goetz, Jason
AU - Mair, Volkmar
AU - Pittore, Massimiliano
N1 - Funding Information:
This research has been supported by the Provincia autonoma di Bolzano – Alto Adige (grant no. 9/34).
Funding Information:
We thank Marta-Cristina Jurchescu and the anonymous reviewer for their valuable feedback, which helped improve the quality of this work. The authors thank the Department of Innovation and Research, University of the Autonomous Province of Bozen/Bolzano, for covering the open access publication costs. The research leading to these results are related to the Proslide project that received funding from the research programme Research Südtirol/Alto Adige 2019 of the Autonomous Province of Bozen/Bolzano – Südtirol/Alto Adige. The authors are grateful to the Autonomous Province of Bolzano for providing access to basic environmental input data. Many thanks also go to Daniel Costantini and Silvia Tagnin of the Provincial Office for Geology and Building Materials Testing for their assistance in the preparation and selection of suitable landslide data.
Publisher Copyright:
© 2023 Copernicus GmbH. All rights reserved.
PY - 2023/4/21
Y1 - 2023/4/21
N2 - The increasing availability of long-term observational data can lead to the development of innovative modelling approaches to determine landslide triggering conditions at a regional scale, opening new avenues for landslide prediction and early warning. This research blends the strengths of existing approaches with the capabilities of generalized additive mixed models (GAMMs) to develop an interpretable approach that identifies seasonally dynamic precipitation conditions for shallow landslides. The model builds upon a 21-year record of landslides in South Tyrol (Italy) and separates precipitation that induced landslides from precipitation that did not. The model accounts for effects acting at four temporal scales: short-term “triggering” precipitation, medium-term “preparatory” precipitation, seasonal effects, and across-year data variability. It provides relative landslide probability scores that were used to establish seasonally dynamic thresholds with optimal performance in terms of hit and false-alarm rates, as well as additional thresholds related to user-defined performance scores. The GAMM shows a high predictive performance and indicates that more precipitation is required to induce a landslide in summer than in winter/spring, which can presumably be attributed mainly to vegetation and temperature effects. The discussion illustrates why the quality of input data, study design, and model transparency are crucial for landslide prediction using advanced data-driven techniques.
AB - The increasing availability of long-term observational data can lead to the development of innovative modelling approaches to determine landslide triggering conditions at a regional scale, opening new avenues for landslide prediction and early warning. This research blends the strengths of existing approaches with the capabilities of generalized additive mixed models (GAMMs) to develop an interpretable approach that identifies seasonally dynamic precipitation conditions for shallow landslides. The model builds upon a 21-year record of landslides in South Tyrol (Italy) and separates precipitation that induced landslides from precipitation that did not. The model accounts for effects acting at four temporal scales: short-term “triggering” precipitation, medium-term “preparatory” precipitation, seasonal effects, and across-year data variability. It provides relative landslide probability scores that were used to establish seasonally dynamic thresholds with optimal performance in terms of hit and false-alarm rates, as well as additional thresholds related to user-defined performance scores. The GAMM shows a high predictive performance and indicates that more precipitation is required to induce a landslide in summer than in winter/spring, which can presumably be attributed mainly to vegetation and temperature effects. The discussion illustrates why the quality of input data, study design, and model transparency are crucial for landslide prediction using advanced data-driven techniques.
KW - ITC-ISI-JOURNAL-ARTICLE
KW - ITC-GOLD
U2 - 10.5194/nhess-23-1483-2023
DO - 10.5194/nhess-23-1483-2023
M3 - Article
SN - 1561-8633
VL - 23
SP - 1483
EP - 1506
JO - Natural hazards and earth system sciences
JF - Natural hazards and earth system sciences
IS - 4
ER -