From Data to Application: Harnessing Big Spatial Data and Spatially Explicit Machine Learning Model for Landslide Susceptibility Prediction and Mapping
Pages 10 - 19
Abstract
Recent advancements in information and communication technology have significantly enhanced access to extensive geospatial data, presenting a valuable opportunity to leverage big spatial data for improved modeling and predictive capabilities in natural disaster risk assessment. This paper explores the integration of a comprehensive dataset comprising historical landslide events and various geo-environmental variables within a spatially explicit machine learning framework. The study empirically demonstrates that incorporating big spatial data allows a more nuanced understanding of local variations and spatial dependencies. Ultimately, this empirical assessment produces more accurate landslide risk predictions than traditional baseline models. Using Italy's expansive Valtellina Valley as a case study covering over 3,308 km2, the study illustrates the potential of this integrated approach to enhance predictive outcomes and improve the granularity of the produced landslide susceptibility risk map. The study findings underscore the transformative potential of big spatial data in improving landslide susceptibility assessment and supporting informed decisions in disaster risk management and preparedness.
References
[1]
Antonio Cendrero, Luis M. Forte, Juan Remondo, and Juan A. Cuesta-Albertos. 2020. Anthropocene Geomorphic Change. climate or human activities? Earth's Future 8, 5 (2020).
[2]
Melanie J. Froude and David N. Petley. 2018. Global fatal landslide occurrence from 2004 to 2016. Natural Hazards and Earth System Sciences 18, 8 (August 2018), 2161--2181.
[3]
Mihail E. Popescu and Katsuo Sasahara. 2009. Engineering measures for landslide disaster mitigation. Landslides - Disaster Risk Reduction (2009), 609--631.
[4]
Luigi Lombardo, Hakan Tanyas, Raphaël Huser, Fausto Guzzetti, Daniela Castro Camilo, Landslide size matters: A new data-driven, spatial prototype, Engineering Geology, Volume 293, 2021, 106288, ISSN 0013-7952, https://doi.org/10.1016/j.enggeo.2021.106288.
[5]
Sven Müller, Pascal Wilhelm, and Knut Haase. 2013. Spatial dependencies and Spatial Drift in public transport seasonal ticket revenue data. Journal of Retailing and Consumer Services 20, 3 (2013), 334--348.
[6]
Xiaojian Liu, Ourania Kounadi, and Raul Zurita-Milla. 2022. Incorporating spatial autocorrelation in machine learning models using spatial lag and eigenvector spatial filtering features. ISPRS International Journal of Geo-Information 11, 4 (2022), 242.
[7]
Khant Min Naing, Victoria Grace Ann, and Tin Seong Kam. 2024. Is There a Space in Landslide Susceptibility Modeling: Case Study of Valtellina Valley in Italy. Osvaldo Gervasi, Beniamino Murgante, Chiara Garau, David Taniar, Ana Maria A. C. Rocha, Maria Noelia Faginas Lago, eds. Computational Science and Its Applications - ICCSA 2024. ICCSA 2024. Lecture Notes in Computer Science 14813 (2024), 221--238.
[8]
Krishna Chandra Devkota et al. 2012. Landslide susceptibility mapping using certainty factor, index of entropy and logistic regression models in GIS and their comparison at Mugling-Narayanghat Road section in Nepal himalaya. Natural Hazards 65, 1 (2012), 135--165.
[9]
Muhammad Bello Ibrahim, Zahiraniza Mustaffa, Abdul-Lateef Balogun, Indra Sati Hamonangan Harahap, and Mudassir Ali Khan. 2021. Advanced data mining techniques for landslide susceptibility mapping. Geomatics, Natural Hazards and Risk 12, 1 (2021), 2430--2461.
[10]
Yange Li, Xintong Liu, Zheng Han, and Jie Dou. 2020. Spatial proximity-based geographically weighted regression model for landslide susceptibility assessment: A case study of qingchuan area, China. Applied Sciences 10, 3 (2020), 1107.
[11]
Jagabandhu Roy and Sunil Saha. 2019. Landslide susceptibility mapping using knowledge driven statistical models in Darjeeling district, West Bengal, India. Geoenvironmental Disasters 6, 1 (August 2019).
[12]
S. Boussouf, T. Fernández, and A.B. Hart. 2023. Landslide susceptibility mapping using maximum entropy (Maxent) and geographically weighted logistic regression (GWLR) models in the Río Aguas catchment (Almería, SE Spain). Natural Hazards 117, 1 (2023), 207--235.
[13]
Dalia Kirschbaum, Thomas Stanley, and Yaping Zhou. 2015. Spatial and temporal analysis of a global landslide catalog. Geomorphology 249 (2015), 4--15.
[14]
Gazali Agboola, Leila Hashemi Beni, Tamer Elbayoumi and Gary Thompson. 2024. Optimizing landslide susceptibility mapping using machine learning and Geospatial Techniques. Ecological Informatics 81 (2024), 102583.
[15]
Li Zhu et al. 2020. Landslide susceptibility prediction modeling based on Remote Sensing and a novel deep learning algorithm of a cascade-parallel recurrent neural network. Sensors 20, 6 (2020), 1576.
[16]
Fang Zou, Ying Xiong, and Xilu Chen. 2022. Spatial modeling to assess geohazard susceptibility assessment in the mountainous Shennongjia area of China. Arabian Journal of Geosciences 15, 23 (2022).
[17]
Behnam Nikparvar and Jean-Claude Thill. 2021. Machine learning of Spatial Data. ISPRS International Journal of Geo-Information 10, 9 (2021), 600.
[18]
Aynaz Lotfata, George Grekousis, and Ruoyu Wang. 2023. Using geographical random forest models to explore spatial patterns in the neighborhood determinants of hypertension prevalence across Chicago, Illinois, USA. Environment and Planning B: Urban Analytics and City Science 50, 9 (2023), 2376--2393.
[19]
Isabella Gollini, Binbin Lu, Martin Charlton, Christopher Brunsdon, and Paul Harris. 2015. GWmodel: An R Package for Exploring Spatial Heterogeneity Using Geographically Weighted Models. Journal of Statistical Software, 63(17), 1--50.
[20]
Binbin Lu, Paul Harris, Martin Charlton, and Chris Brunsdon. 2014. The gwmodel R package: Further topics for exploring spatial heterogeneity using geographically weighted models. Geo-spatial Information Science 17, 2 (2014), 85--101.
[21]
Marvin N. Wright and Andreas Ziegler. 2017. ranger: A fast implementation of random forests for high dimensional data in C++ and R. Journal of Statistical Software 77, 1 (2017).
[22]
Stamatis Kalogirou and Stefanos Georganos. 2024. SpatialML: Spatial Machine Learning. R package version 0.1.7. https://cran.rproject.org/web/packages/SpatialML/
[23]
Alexander Stewart Fotheringham, Chris Brunsdon, and Martin Charlton. 2010. Geographically weighted regression the analysis of spatially varying relationships, Chichester: Wiley.
[24]
Stephen A. Matthews and Tse-Chuan Yang. 2012. Mapping the results of local statistics. Demographic Research 26 (2012), 151--166.
[25]
Raphael Couronné, Philipp Probst, and Anne-Laure Boulesteix. 2018. Random Forest versus logistic regression: A large-scale benchmark experiment. BMC Bioinformatics 19, 1 (2018).
[26]
Stefanos Georganos and Stamatis Kalogirou. 2022. A forest of forests: A spatially weighted and computationally efficient formulation of geographical random forests. ISPRS International Journal of Geo-Information 11, 9 (2022), 471.
[27]
David Alexander. 1988. Valtellina landslide and flood emergency, Northern Italy, 1987. Disasters 12, 3 (1988), 212--222.
[28]
Fabio Luino et al. 2022. The role of soil type in triggering shallow landslides in the Alps (Lombardy, Northern Italy). Land 11, 8 (2022), 1125.
[29]
Qiongjie Xu, Vasil Yordanov, & Maria Antonia Brovelli. Landslide Influencing Factors for Landslide Susceptibility Mapping in Lombardy, Italy [Dataset]. Zenodo.
[30]
Liping Di and Eugene Yu. 2023. Challenges and opportunities in remote sensing Big Data. Springer Remote Sensing/Photogrammetry (2023), 281--291.
Index Terms
- From Data to Application: Harnessing Big Spatial Data and Spatially Explicit Machine Learning Model for Landslide Susceptibility Prediction and Mapping
Recommendations
Manifestation of an adaptive neuro-fuzzy model on landslide susceptibility mapping: Klang valley, Malaysia
The purpose of the present paper is to manifest the results of the neuro-fuzzy model using remote sensing data and GIS for landslide susceptibility analysis in a part of the Klang Valley areas i Malaysia. Landslide locations in the study area were ...
Application of the analytical hierarchy process (AHP) for landslide susceptibility mapping: A case study from the Tinau watershed, west Nepal
Landslide problems are abundant in the mountainous areas of Nepal due to a unique combination of adverse geological conditions, abundant rainfall and anthropogenic factors, which leads to enormous loss of life and property every year. To control such ...
Data-model fusion for improving LAI mapping: a case study over China's land mass
A simple data-model fusion method is developed to improve leaf area index LAI mapping using satellite data. The objective is to overcome two issues with satellite-derived LAI maps: 1 optical remote sensing data are often seriously affected by the ...
Comments
Please enable JavaScript to view thecomments powered by Disqus.Information & Contributors
Information
Published In
October 2024
40 pages
ISBN:9798400711435
DOI:10.1145/3681763
Copyright © 2024 Owner/Author.
This work is licensed under a Creative Commons Attribution International 4.0 License.
Sponsors
Publisher
Association for Computing Machinery
New York, NY, United States
Publication History
Published: 29 October 2024
Check for updates
Author Tags
Qualifiers
- Research-article
- Research
- Refereed limited
Conference
SIGSPATIAL '24
Sponsor:
SIGSPATIAL '24: The 32nd ACM International Conference on Advances in Geographic Information Systems
October 29 - November 1, 2024
GA, Atlanta, USA
Acceptance Rates
Overall Acceptance Rate 32 of 58 submissions, 55%
Contributors
Other Metrics
Bibliometrics & Citations
Bibliometrics
Article Metrics
- 0Total Citations
- 77Total Downloads
- Downloads (Last 12 months)77
- Downloads (Last 6 weeks)77
Reflects downloads up to 10 Dec 2024
Other Metrics
Citations
View Options
Login options
Check if you have access through your login credentials or your institution to get full access on this article.
Sign in