A machine learning framework for multi-hazards modeling and mapping in a mountainous area

This study sought to produce an accurate multi-hazard risk map for a mountainous region of Iran. The study area is in southwestern Iran. The region has experienced numerous extreme natural events in recent decades. This study models the probabilities of snow avalanches, landslides, wildfires, land subsidence, and floods using machine learning models that include support vector machine (SVM), boosted regression tree (BRT), and generalized linear model (GLM). Climatic, topographic, geological, social, and morphological factors were the main input variables used. The data were obtained from several sources. The accuracies of GLM, SVM, and functional discriminant analysis (FDA) models indicate that SVM is the most accurate for predicting landslides, land subsidence, and flood hazards in the study area. GLM is the best algorithm for wildfire mapping, and FDA is the most accurate model for predicting snow avalanche risk. The values of AUC (area under curve) for all five hazards using the best models are greater than 0.8, demonstrating that the model’s predictive abilities are acceptable. A machine learning approach can prove to be very useful tool for hazard management and disaster mitigation, particularly for multi-hazard modeling. The predictive maps produce valuable baselines for risk management in the study area, providing evidence to manage future human interaction with hazards.

[1]  M. Cavalli,et al.  Exploiting LSPIV to assess debris-flow velocities in the field , 2017 .

[2]  Bahareh Kalantar,et al.  Groundwater potential mapping using C5.0, random forest, and multivariate adaptive regression spline models in GIS , 2018, Environmental Monitoring and Assessment.

[3]  M. Vasconcelos,et al.  Spatial Prediction of Fire Ignition Probabilities: Comparing Logistic Regression and Neural Networks , 2001 .

[4]  Xiwei Xu,et al.  Comparison of different models for susceptibility mapping of earthquake triggered landslides related with the 2008 Wenchuan earthquake in China , 2012, Comput. Geosci..

[5]  Jeffrey J. McDonnell,et al.  Hydrological connectivity of hillslopes and streams: Characteristic time scales and nonlinearities , 2010 .

[6]  Eric Neumayer,et al.  A trend analysis of normalized insured damage from natural disasters , 2011, Climatic Change.

[7]  H. Pourghasemi,et al.  Is multi-hazard mapping effective in assessing natural hazards and integrated watershed management? , 2020 .

[8]  L. W. Zevenbergen,et al.  A METHODOLOGY FOR PREDICTING CHANNEL MIGRATION NCHRP PROJECT NO. 24-26 , 2001 .

[9]  Ian Burton,et al.  The hazardousness of a place: A regional ecology of damaging events , 1971 .

[10]  Dieu Tien Bui,et al.  Tropical Forest Fire Susceptibility Mapping at the Cat Ba National Park Area, Hai Phong City, Vietnam, Using GIS-Based Kernel Logistic Regression , 2016, Remote. Sens..

[11]  P. Tarolli,et al.  Soil water erosion on Mediterranean vineyards: A review , 2015 .

[12]  Malcolm K. Hughes,et al.  Topographically modified tree-ring chronologies as a potential means to improve paleoclimate inference , 2011 .

[13]  S. Pascale,et al.  Evaluation of prediction capability of the artificial neural networks for mapping landslide susceptibility in the Turbolo River catchment (northern Calabria, Italy) , 2014 .

[14]  Chris T. Kiranoudis,et al.  A GIS based operational system for wildland fire crisis management I. Mathematical modelling and simulation , 2004 .

[15]  P. Aleotti,et al.  Landslide hazard assessment: summary review and new perspectives , 1999 .

[16]  Andreas Stoffel,et al.  Automated identification of potential snow avalanche release areas based on digital elevation models , 2013 .

[17]  Martin Haigh,et al.  Interactions between forest and landslide activity along new highways in the Kumaun Himalaya , 1995 .

[18]  Dawei Han,et al.  Flood forecasting using support vector machines , 2007 .

[19]  P. Robichaud,et al.  Fire Effects on Soil Infiltration , 2009 .

[20]  Zhi Guang Li,et al.  Research on Prediction Model of Support Vector Machine Based Land Subsidence Caused by Foundation Pit Dewatering , 2013 .

[21]  Pijush Samui,et al.  A novel hybrid approach based on a swarm intelligence optimized extreme learning machine for flash flood susceptibility mapping , 2019, CATENA.

[22]  R. Trigo,et al.  Global fire activity patterns (1996–2006) and climatic influence: an analysis using the World Fire Atlas , 2007 .

[23]  Andreas Stoffel,et al.  Automated snow avalanche release area delineation – validation of existing algorithms and proposition of a new object-based approach for large-scale hazard indication mapping , 2018, Natural Hazards and Earth System Sciences.

[24]  T. Glade,et al.  From single- to multi-hazard risk analyses: a concept addressing emerging challenges , 2010 .

[25]  Biswajeet Pradhan,et al.  Spatial prediction models for shallow landslide hazards: a comparative assessment of the efficacy of support vector machines, artificial neural networks, kernel logistic regression, and logistic model tree , 2016, Landslides.

[26]  John Kelly,et al.  A conceptual model of avalanche hazard , 2017, Natural Hazards.

[27]  Hamid Reza Pourghasemi,et al.  Spatial modelling of gully headcuts using UAV data and four best-first decision classifier ensembles (BFTree, Bag-BFTree, RS-BFTree, and RF-BFTree) , 2019, Geomorphology.

[28]  M. Marschalko,et al.  Landslide susceptibility assessment of the Kraľovany–Liptovský Mikuláš railway case study , 2010 .

[29]  José I. Barredo,et al.  Major flood disasters in Europe: 1950–2005 , 2007 .

[30]  I-Fan Chang,et al.  Support vector regression for real-time flood stage forecasting , 2006 .

[31]  O. Sass,et al.  Using multi variate data mining techniques for estimating fire susceptibility of Tyrolean forests , 2014 .

[32]  Joel C. Gill,et al.  Reviewing and visualizing the interactions of natural hazards , 2014 .

[33]  P. Reichenbach,et al.  Landslide hazard evaluation: a review of current techniques and their application in a multi-scale study, Central Italy , 1999 .

[34]  Stephanie F. Pilkington,et al.  Spatial and temporal variations in resilience to tropical cyclones along the United States coastline as determined by the multi-hazard hurricane impact level model , 2017, Palgrave Communications.

[35]  Hervé Glotin,et al.  Functional Mixture Discriminant Analysis with hidden process regression for curve classification , 2012, ESANN.

[36]  Yves Bühler,et al.  Sensitivity of snow avalanche simulations to digital elevation model quality and resolution , 2011, Annals of Glaciology.

[37]  B. R. Ramesh,et al.  Environmental susceptibility model for predicting forest fire occurrence in the Western Ghats of India , 2012 .

[38]  H. Pourghasemi GIS-based forest fire susceptibility mapping in Iran: a comparison between evidential belief function and binary logistic regression models , 2016 .

[39]  Ni-Bin Chang,et al.  Combining GIS with fuzzy multicriteria decision-making for landfill siting in a fast-growing urban region. , 2008, Journal of environmental management.

[40]  S. Liang,et al.  Fisher discriminant analysis for classification of autism spectrum disorders based on folate-related metabolism markers. , 2019, The Journal of nutritional biochemistry.

[41]  C. F. Lee,et al.  GIS-based geo-environmental evaluation for urban land-use planning: A case study , 2001 .

[42]  H. Pourghasemi,et al.  Assessment of the importance of gully erosion effective factors using Boruta algorithm and its spatial modeling and mapping using three machine learning algorithms , 2019, Geoderma.

[43]  P. Bala,et al.  Why do people use food delivery apps (FDA)? A uses and gratification theory perspective , 2019, Journal of Retailing and Consumer Services.

[44]  H. Pourghasemi,et al.  Multi-hazard probability assessment and mapping in Iran. , 2019, The Science of the total environment.

[45]  J. Hanley,et al.  The meaning and use of the area under a receiver operating characteristic (ROC) curve. , 1982, Radiology.

[46]  Corinna Cortes,et al.  Support-Vector Networks , 1995, Machine Learning.

[47]  Joel C. Gill,et al.  Hazard interactions and interaction networks (cascades) within multi-hazardmethodologies , 2016 .

[48]  D. Mcclung,et al.  The Avalanche Handbook , 1993 .

[49]  Robert Y. Liang,et al.  A method for slope stability analysis considering subsurface stratigraphic uncertainty , 2018, Landslides.

[50]  S. Evans,et al.  Magnitude and frequency of rock falls and rock slides along the main transportation corridors of southwestern British Columbia , 1999 .

[51]  Antoine Guisan,et al.  Predictive habitat distribution models in ecology , 2000 .

[52]  Taylor Clark,et al.  Exploring the link between the Conceptual Model of Avalanche Hazard and the North American Public Avalanche Danger Scale , 2019 .

[53]  David W. Hosmer,et al.  Applied Logistic Regression , 1991 .

[54]  Tien-Dat Pham,et al.  Multi-Hazard Exposure Mapping Using Machine Learning Techniques: A Case Study from Iran , 2019, Remote. Sens..

[55]  D. Riaño,et al.  Multitemporal Modelling of Socio-Economic Wildfire Drivers in Central Spain between the 1980s and the 2000s: Comparing Generalized Linear Models to Machine Learning Algorithms , 2016, PloS one.

[56]  C. Marzban The ROC Curve and the Area under It as Performance Measures , 2004 .

[57]  J. Gerring A case study , 2011, Technology and Society.

[58]  B. Mohanty,et al.  Risk Mapping Analysis With Geographic Information Systems for Landslides Using Supply Chain , 2019, Emerging Applications in Supply Chains for Sustainable Business Development.

[59]  Leo Breiman,et al.  Random Forests , 2001, Machine Learning.

[60]  Xudong Zhang,et al.  Classification and regression with random forests as a standard method for presence-only data SDMs: A future conservation example using China tree species , 2019, Ecol. Informatics.

[61]  Hamid Reza Pourghasemi,et al.  A comparative assessment of prediction capabilities of modified analytical hierarchy process (M-AHP) and Mamdani fuzzy logic models using Netcad-GIS for forest fire susceptibility mapping , 2016 .

[62]  A. C. Demirkesen,et al.  Multi-risk interpretation of natural hazards for settlements of the Hatay province in the east Mediterranean region, Turkey using SRTM DEM , 2012, Environmental Earth Sciences.

[63]  V. Nikitović Functional data analysis in forecasting Serbian fertility , 2011 .

[64]  Z. Q. John Lu,et al.  Nonparametric Functional Data Analysis: Theory And Practice , 2007, Technometrics.

[65]  Daniel Germain,et al.  Snow avalanche hazard assessment and risk management in northern Quebec, eastern Canada , 2015, Natural Hazards.

[66]  Juan de la Riva,et al.  An insight into machine-learning algorithms to model human-caused wildfire occurrence , 2014, Environ. Model. Softw..

[67]  H. Pourghasemi,et al.  Prioritization of effective factors in the occurrence of land subsidence and its susceptibility mapping using an SVM model and their different kernel functions , 2018, Bulletin of Engineering Geology and the Environment.

[68]  Saeedeh Eskandari,et al.  Fire danger assessment in Iran based on geospatial information , 2015, Int. J. Appl. Earth Obs. Geoinformation.

[69]  Margreth Keiler,et al.  Challenges of analyzing multi-hazard risk: a review , 2012, Natural Hazards.

[70]  Hamid Reza Pourghasemi,et al.  Erratum to: Landslide susceptibility mapping using random forest, boosted regression tree, classification and regression tree, and general linear models and comparison of their performance at Wadi Tayyah Basin, Asir Region, Saudi Arabia , 2016, Landslides.

[71]  Tamar Frankel [The theory and the practice...]. , 2001, Tijdschrift voor diergeneeskunde.

[72]  Stephanie F. Pilkington,et al.  Real-time Application of the Multihazard Hurricane Impact Level Model for the Atlantic Basin , 2017, Front. Built Environ..

[73]  Francesco Ferro,et al.  Avalanche hazard mapping over large undocumented areas , 2011 .

[74]  차용진 Risk Perception and Acceptance , 2005 .

[75]  Avi Bar Massada,et al.  Wildfire ignition-distribution modelling: a comparative study in the Huron-Manistee National Forest, Michigan, USA , 2013 .

[76]  Christian Nansen,et al.  Remote Sensing and Reflectance Profiling in Entomology. , 2016, Annual review of entomology.

[77]  Mollie E. Brooks,et al.  Generalized linear mixed models: a practical guide for ecology and evolution. , 2009, Trends in ecology & evolution.

[78]  Flaviu Meseșan,et al.  Reconstructing snow-avalanche extent using remote sensing and dendrogeomorphology in Parâng Mountains , 2019, Cold Regions Science and Technology.

[79]  Saro Lee Application and verification of fuzzy algebraic operators to landslide susceptibility mapping , 2007 .

[80]  E. Rotigliano,et al.  Improving transferability strategies for debris flow susceptibility assessment: Application to the Saponara and Itala catchments (Messina, Italy) , 2017 .

[81]  Andreas Christmann,et al.  Support vector machines , 2008, Data Mining and Knowledge Discovery Handbook.

[82]  Himan Shahabi,et al.  Application of MODIS image satellite and GIS technique in assessment of avalanche fall in roads , 2011 .

[83]  David G. E. Liverman,et al.  Snow Avalanche Hazard in Canada – a Review , 2003 .

[84]  Alexandra D. Syphard,et al.  Simulating fire frequency and urban growth in southern California coastal shrublands, USA , 2007, Landscape Ecology.

[85]  H. Pourghasemi,et al.  Landslide susceptibility mapping by binary logistic regression, analytical hierarchy process, and statistical index models and assessment of their performances , 2013, Natural Hazards.

[86]  R Fell,et al.  Landslides: risk perception and acceptance , 1997 .

[87]  A. Ribolini,et al.  Multidisciplinary investigations in evaluating landslide susceptibility—An example in the Serchio River valley (Italy) , 2007 .

[88]  A. Assadzadeh,et al.  A Case Study of Iran , 2001 .

[89]  Bruce D. Malamud,et al.  Hazard Interactions and Interaction Networks (Cascades) within Multi-Hazard Methodologies , 2016 .

[90]  Hamid Reza Pourghasemi,et al.  Effects of urbanization on river morphology of the Talar River, Mazandarn Province, Iran , 2019 .

[91]  H. Tabari,et al.  Temporal trends and spatial characteristics of drought and rainfall in arid and semiarid regions of Iran , 2012 .

[92]  A. Ozdemir,et al.  A comparative study of frequency ratio, weights of evidence and logistic regression methods for landslide susceptibility mapping: Sultan Mountains, SW Turkey , 2013 .

[93]  Sarah E. Edwards,et al.  An interrelated hazards approach to anticipating evolving risk , 2016 .

[94]  K. Feigl,et al.  Radar interferometry and its application to changes in the Earth's surface , 1998 .

[95]  Omid Rahmati,et al.  Flood hazard zoning in Yasooj region, Iran, using GIS and multi-criteria decision analysis , 2016 .

[96]  Mathieu Marmion,et al.  A comparison of predictive methods in modelling the distribution of periglacial landforms in Finnish Lapland , 2008 .

[97]  Wei Chen,et al.  Spatial prediction of landslide susceptibility using data mining-based kernel logistic regression, naive Bayes and RBFNetwork models for the Long County area (China) , 2019, Bulletin of Engineering Geology and the Environment.

[98]  E. Chuvieco,et al.  Development of a framework for fire risk assessment using remote sensing and geographic information system technologies , 2010 .

[99]  Emmanouil N. Anagnostou,et al.  Sensitivity of a mountain basin flash flood to initial wetness condition and rainfall variability , 2011 .

[100]  Jun Xu,et al.  Adaptive scaled unscented transformation for highly efficient structural reliability analysis by maximum entropy method , 2019, Structural Safety.

[101]  Mikhail Kanevski,et al.  Forest Fires in a Random Forest , 2013 .

[102]  Αλέξανδρος Π. Αλεξανδρίδης,et al.  A GIS based operational system for wildland fire crisis management I , 2015 .

[103]  Peter F. Lagasse,et al.  METHODOLOGY FOR PREDICTING CHANNEL MIGRATION , 2004 .

[104]  Yu Huang,et al.  Review on landslide susceptibility mapping using support vector machines , 2018, CATENA.

[105]  H. Pourghasemi,et al.  Evaluating the influence of geo-environmental factors on gully erosion in a semi-arid region of Iran: An integrated framework. , 2017, The Science of the total environment.

[106]  Samsung Lim,et al.  Modelling spatial patterns of wildfire occurrence in South-Eastern Australia , 2016 .

[107]  Saeid Eslamian,et al.  Investigation of climate change in Iran. , 2010 .

[108]  Seyed Amir Naghibi,et al.  A Comparative Assessment Between Three Machine Learning Models and Their Performance Comparison by Bivariate and Multivariate Statistical Methods in Groundwater Potential Mapping , 2015, Water Resources Management.

[109]  Saeedeh Eskandari,et al.  A new approach for forest fire risk modeling using fuzzy AHP and GIS in Hyrcanian forests of Iran , 2017, Arabian Journal of Geosciences.

[110]  D. Ruppert The Elements of Statistical Learning: Data Mining, Inference, and Prediction , 2004 .

[111]  J. Oldeland,et al.  Modelling potential distribution of the threatened tree species Juniperus oxycedrus: how to evaluate the predictions of different modelling approaches? , 2011 .

[112]  Zohre Sadat Pourtaghi,et al.  Investigation of general indicators influencing on forest fire and its susceptibility modeling using different data mining techniques , 2016 .

[113]  Peter A. Troch,et al.  The future of hydrology: An evolving science for a changing world , 2010 .

[114]  James O. Ramsay,et al.  Applied Functional Data Analysis: Methods and Case Studies , 2002 .

[115]  E. Chuvieco,et al.  Human-caused wildfire risk rating for prevention planning in Spain. , 2009, Journal of environmental management.

[116]  Chris Stethem,et al.  Snow Avalanche Hazards and Management in Canada: Challenges and Progress , 2002 .

[117]  Ching-Hsue Cheng Evaluating naval tactical missile systems by fuzzy AHP based on the grade value of membership function , 1997 .

[118]  H. Pourghasemi,et al.  Habitat Suitability Mapping of Artemisia aucheri Boiss Based on the GLM Model in R , 2019, Spatial Modeling in GIS and R for Earth and Environmental Sciences.

[119]  J. Rockström,et al.  An Integrated Framework for , 2015 .

[120]  Zohre Sadat Pourtaghi,et al.  Landslide susceptibility mapping using random forest, boosted regression tree, classification and regression tree, and general linear models and comparison of their performance at Wadi Tayyah Basin, Asir Region, Saudi Arabia , 2015, Landslides.

[121]  K. Taalab,et al.  Flood Prediction Using Support Vector Machines (SVM) , 2016 .

[122]  Benoît Stoll,et al.  Support vector machines to map rare and endangered native plants in Pacific islands forests , 2012, Ecol. Informatics.

[123]  Thomas Glade,et al.  Multi-hazard Analysis In NaturalRisk Assessments , 2011 .

[124]  Hamid Reza Pourghasemi,et al.  Accuracy assessment of land cover/land use classifiers in dry and humid areas of Iran , 2015, Environmental Monitoring and Assessment.

[125]  D. Varnes SLOPE MOVEMENT TYPES AND PROCESSES , 1978 .

[126]  Hyun-Joo Oh,et al.  Integration of ground subsidence hazard maps of abandoned coal mines in Samcheok, Korea , 2011 .

[127]  Hyun-Joo Oh,et al.  Prediction of ground subsidence in Samcheok City, Korea using artificial neural networks and GIS , 2009 .

[128]  J. Pereira,et al.  Modeling spatial patterns of fire occurrence in Mediterranean Europe using Multiple Regression and Random Forest , 2012 .

[129]  F. J. Lozano,et al.  A multi-scale approach for modeling fire occurrence probability using satellite data and classification trees: A case study in a mountainous Mediterranean region , 2008 .

[130]  Michael Dumbser,et al.  On GLM curl cleaning for a first order reduction of the CCZ4 formulation of the Einstein field equations , 2020, J. Comput. Phys..

[131]  S. Berberoglu,et al.  Mapping regional forest fire probability using artificial neural network model in a Mediterranean forest ecosystem , 2016 .

[132]  Hamid Reza Pourghasemi,et al.  Effects of hydrological events on morphological evolution of a fluvial system , 2018, Journal of Hydrology.

[133]  Graham A. Tobin,et al.  Natural Hazards: Explanation and Integration , 1997 .

[134]  George Gaprindashvili,et al.  Hazard Risk of Debris/Mud Flow Events in Georgia and Methodological Approaches for Management , 2018, IAEG/AEG Annual Meeting Proceedings, San Francisco, California, 2018 - Volume 5.

[135]  Daniele Bocchiola,et al.  Modelling soil removal from snow avalanches: A case study in the North-Western Italian Alps , 2012 .

[136]  Kostas Kalabokidis,et al.  Identifying wildland fire ignition factors through sensitivity analysis of a neural network , 2009 .

[137]  Peter Berck,et al.  Incorporating Anthropogenic Influences into Fire Probability Models: Effects of Human Activity and Climate Change on Fire Activity in California , 2016, PloS one.

[138]  H. Pourghasemi,et al.  Predicting Habitat Suitability and Conserving Juniperus spp. Habitat Using SVM and Maximum Entropy Machine Learning Techniques , 2019, Water.

[139]  Neil I. Fox,et al.  A study of twentieth‐century extreme rainfall events in the United Kingdom with implications for forecasting , 2004 .

[140]  H. Pourghasemi,et al.  Testing a New Ensemble Model Based on SVM and Random Forest in Forest Fire Susceptibility Assessment and Its Mapping in Serbia’s Tara National Park , 2019, Forests.

[141]  Michel Jaboyedoff,et al.  Rockfall hazard and risk assessments along roads at a regional scale: example in Swiss Alps , 2012 .

[142]  Alexandra D. Syphard,et al.  Predicting spatial patterns of fire on a southern California landscape , 2008 .

[143]  M. Sorriso-Valvo,et al.  Logistic Regression analysis in the evaluation of mass movements susceptibility : The Aspromonte case study, Calabria, Italy , 2007 .

[144]  Crystal A. Kolden,et al.  Relationships between climate and macroscale area burned in the western United States , 2013 .

[145]  P. Reichenbach,et al.  Probabilistic landslide hazard assessment at the basin scale , 2005 .

[146]  S. Keesstra,et al.  Identifying tree health using sentinel-2 images: a case study on Tortrix viridana L. infected oak trees in Western Iran , 2020, Geocarto International.

[147]  Robert C. Wolpert,et al.  A Review of the , 1985 .

[148]  Hamid Reza Pourghasemi,et al.  A comparative assessment between linear and quadratic discriminant analyses (LDA-QDA) with frequency ratio and weights-of-evidence models for forest fire susceptibility mapping in China , 2017, Arabian Journal of Geosciences.

[149]  R. Lasaponara,et al.  Application of learning vector quantization and different machine learning techniques to assessing forest fire influence factors and spatial modelling. , 2020, Environmental research.

[150]  Mikhail F. Kanevski,et al.  Wildfire susceptibility mapping: Deterministic vs. stochastic approaches , 2018, Environ. Model. Softw..

[151]  Robert G. Bell,et al.  Quantitative multi-risk analysis for natural hazards: a framework for multi-risk modelling , 2011 .

[152]  Krishna Prasad Vadrevu,et al.  Fire risk evaluation using multicriteria analysis—a case study , 2010, Environmental monitoring and assessment.

[153]  Martin Mergili,et al.  Regional-scale analysis of high-mountain multi-hazard and risk indicators in the Pamir (Tajikistan) with GRASS GIS , 2013 .

[154]  Andreas Paul Zischg,et al.  A spatiotemporal multi-hazard exposure assessment based on property data , 2015 .

[155]  H. Pourghasemi,et al.  Performance assessment of individual and ensemble data-mining techniques for gully erosion modeling. , 2017, The Science of the total environment.

[156]  C. Christophe,et al.  Spatio-temporal reconstruction of snow avalanche activity using tree rings: Pierres Jean Jeanne aval , 2010 .

[157]  Trevor Hastie,et al.  Support Vector Machines , 2013 .

[158]  Giovanni Pardini,et al.  Runoff erosion and nutrient depletion in five Mediterranean soils of NE Spain under different land use. , 2003, The Science of the total environment.

[159]  B. Pham,et al.  Landslide susceptibility assesssment in the Uttarakhand area (India) using GIS: a comparison study of prediction capability of naïve bayes, multilayer perceptron neural networks, and functional trees methods , 2017, Theoretical and Applied Climatology.

[160]  M. Marjanović,et al.  Landslide susceptibility assessment using SVM machine learning algorithm , 2011 .

[161]  H. Pourghasemi,et al.  Application of GIS-based data driven random forest and maximum entropy models for groundwater potential mapping: A case study at Mehran Region, Iran , 2016 .

[162]  Hossein Bahrainy NATURAL DISASTER MANAGEMENT IN IRAN DURING THE 1990S--NEED FOR A NEW STRUCTURE , 2003 .

[163]  Lee Saro,et al.  Ensemble of ground subsidence hazard maps using fuzzy logic , 2014 .

[164]  Biswajeet Pradhan,et al.  Assessment of Landslide Susceptibility Using Statistical- and Artificial Intelligence-Based FR-RF Integrated Model and Multiresolution DEMs , 2019, Remote. Sens..

[165]  H. Pourghasemi,et al.  Assessing and mapping multi-hazard risk susceptibility using a machine learning technique , 2020, Scientific Reports.