nach oben

Bulletin of Engineering Geology and the Environment

Erschienen in:

22.06.2018 | Original Paper

Predicting the probability of rockfalls occurrence caused by the earthquake of Changureh-Avaj in 2002 using LR, MLP, and RBF methods

verfasst von: V. Bagheri, A. Uromeihy, S. M. Fatemi Aghda

Erschienen in: Bulletin of Engineering Geology and the Environment | Ausgabe 5/2019

Einloggen

Aktivieren Sie unsere intelligente Suche, um passende Fachinhalte oder Patente zu finden.

search-config

KI-gestützte Suche

Aus

Abstract

Rockfalls pose serious threats to human beings, structures, and lifelines. In the present research, a model was developed to predict the possibility of seismic rockfalls on a regional scale. For this purpose, three models including logistic regression (LR), a multilayer perceptron artificial neural network (MLP), and a radial basis function artificial neural network (RBF) were employed. Bivariate logistic regression is a multivariable statistical method that provides a mathematical model using independent variables to predict the occurrence probability of a given phenomenon at a certain location. Although artificial networks of RBF and MLP are pretty similar, there are some structural differences in the components between these two neural networks. The earthquake of Changureh-Avaj in 2002 was used as a basis and benchmark for the model presented in this work. The sustainable zones predicted by LR, MLP, and RBF methods were compared with a database (distribution map) of seismic rockfalls. The results showed good overlap between RBF-predicted rockfall susceptibility zones and database (distribution map) of seismic rockfalls. Besides, in order to evaluate the statistical results of LR, MLP, and RBF models, the verification parameters with high accuracy such as density ratio (Dr), quality sum (Qs), and Receiver Operating Characteristic Curve (ROC) were used. By analyzing the susceptibility maps and considering the Qs index obtained by LR (2.94) and MLP (3.482), and RBF (4.344), it could be observed that the Qs of RBF were higher than that of LR and MLP. Moreover, based on the obtained value of AUC from LR (0.859), MLP (0.910), and RBF methods (0.956), it is seen that the RBF method provided a higher accuracy in predicting the probability of rockfalls occurrence caused by the earthquake of Changureh-Avaj in 2002 compared to LR and MLP methods.

Vorheriger Artikel Probabilistic evaluation of drilling rate index based on a least square support vector machine and Monte Carlo simulation

Nächster Artikel Dynamic analysis of a long-runout, flow-like landslide at Areletuobie, Yili River valley, northwestern China

Sie haben noch keine Lizenz? Dann Informieren Sie sich jetzt über unsere Produkte:

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 390 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Maschinenbau + Werkstoffe

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

über 102.000 Bücher
über 537 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Finance + Banking
Management + Führung
Marketing + Vertrieb
Maschinenbau + Werkstoffe
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Agliardi F, Crosta GB, Frattini P (2009) Integrating rockfall risk assessment and countermeasure design by 3D modelling techniques. Nat Hazards Earth Syst Sci 9(4):1059CrossRef

Ayalew L, Yamagishi H (2005) The application of GIS-based logistic regression for landslide susceptibility mapping in the Kakuda-Yahiko Mountains, Central Japan. Geomorphology 65(1):15–31CrossRef

Bednarik M, Magulová B, Matys M, Marschalko M (2010) Landslide susceptibility assessment of the Kraľovany–Liptovský Mikuláš railway case study. Physics and Chemistry of the Earth, Parts A/B/C 35(3):162–171CrossRef

Budimir MEA, Atkinson PM, Lewis HG (2015) A systematic review of landslide probability mapping using logistic regression. Landslides 12(3):419–436CrossRef

Cancelli A, Crosta G (1993) Rockfall hazard and risk mapping. In: Proceedings 7th International Conference and Field Workshop on Landslides, Czech-Slovak Rep., Balkema, 69–76

Caniani D, Pascale S, Sdao F, Sole A (2008) Neural networks and landslide susceptibility: a case study of the urban area of Potenza. Nat Hazards 45(1):55–72CrossRef

Capolongo D, Refice A, Mankelow J (2002) Evaluating earthquake-triggered landslide hazard at the basin scale through GIS in the upper Sele river valley. Surv Geophys 23(6):595–625CrossRef

Castelli F, Cavallaro A, Grasso S, Lentini V (2016) Seismic microzoning from synthetic ground motion earthquake scenarios parameters: the case study of the City of Catania (Italy). Soil Dyn Earthq Eng 88:307–327CrossRef

Chau KT, Wong RHC, Liu J, Lee CF (2003) Rockfall hazard analysis for Hong Kong based on rockfall inventory. Rock Mech Rock Eng 36(5):383–408CrossRef

Chauhan S, Sharma M, Arora MK (2010) Landslide susceptibility zonation of the Chamoli region, Garhwal Himalayas, using logistic regression model. Landslides 7(4):411–423CrossRef

Clague JJ, Stead D (Eds.) (2012). Landslides: types, mechanisms and modeling. Cambridge University Press, 436 pp

Constantin M, Bednarik M, Jurchescu MC, Vlaicu M (2011) Landslide susceptibility assessment using the bivariate statistical analysis and the index of entropy in the Sibiciu Basin (Romania). Environmental Earth Sciences 63(2):397–406CrossRef

Corominas J, Copons R, Moya J, Vilaplana JM, Altimir J, Amigó J (2005) Quantitative assessment of the residual risk in a rockfall protected area. Landslides 2(4):343–357CrossRef

Corominas J, Mavrouli O, Ruiz-Carulla R (2017) Rockfall occurrence and fragmentation. In: Workshop on World Landslide Forum. Springer, 75–97

Cox DR (1958) The regression analysis of binary sequences. J R Stat Soc Ser B Methodol 20(2):215–242

Crosta GB, Agliardi F (2003) Failure forecast for large rock slides by surface displacement measurements. Can Geotech J 40(1):176–191CrossRef

Cruden DM, Varnes DJ (1996) Landslide types and processes. In Landslides: Investigation and Mitigation, ed. A. K. Turner and R. L. Schuster. Transportation Research Board, Special Report 247, 36–75

Dashti Marvily M (2008) Landslide hazard zoning using logistic regression (Case Study:A Part of Gamasiab Watershed). M.Sc Thesis. Tarbiat Modares University, [in Persian], 92 pp

Del Gaudio V, Wasowski J (2004) Time probabilistic evaluation of seismically induced landslide hazard in Irpinia (southern Italy). Soil Dyn Earthq Eng 24(12):915–928CrossRef

Del Gaudio V, Pierri P, Wasowski J (2003) An approach to time-probabilistic evaluation of seismically induced landslide hazard. Bull Seismol Soc Am 93(2):557–569CrossRef

Ercanoglu M, Gokceoglu C (2002) Assessment of landslide susceptibility for a landslide-prone area (north of Yenice, NW Turkey) by fuzzy approach. Environ Geol 41:720–730CrossRef

Ermini L, Catani F, Casagli N (2005) Artificial neural networks applied to landslide susceptibility assessment. Geomorphology 66(1):327–343CrossRef

Fatemi Aghda SM, Sarikhani R, Teshneh Lab M (2003) Landslide zonation in Talesh area using the expert systems (MLP network). Journal of Engineering Geology, [in Persian] 1(2):179–192

Garsia-Rodríguez MJ, Malpica JA, Benito B, Díaz M (2008) Susceptibility assessment of earthquake-triggered landslides in El Salvador using logistic regression. Geomorphology 95(3):172–191CrossRef

Gee MD (1992) Classification of landslide hazard zonation methods and a test of predictive capability. Proceedings of 6^th international symposium on landslides, Christchurch. New Zealand 2:947–952

Gomez H, Kavzoglu T (2005) Assessment of shallow landslide susceptibility using artificial neural networks in Jabonosa River basin, Venezuela. Eng Geol 78(1):11–27CrossRef

Gosar A (2017) Earthquake-Induced rockfalls caused by 1998 Mw5. 6 Earthquake in Krn Mountains (NW Slovenia) and ESI 2007 Intensity Scale. In: Workshop on World Landslide Forum. Springer, 131–139

Hagan MT, Demuth HB, Beale MH, Jesús OD (2014) Neural network design. Martin Hagan (2 edition), 1012 pp

Hungr O, Evans SG, Hazzard J (1999) Magnitude and frequency of rock falls and rock slides along the main transportation corridors of southwestern British Columbia. Can Geotech J 36(2):224–238CrossRef

Jaboyedoff M, Dudt JP, Labiouse V (2005) An attempt to refine rockfall hazard zoning based on the kinetic energy, frequency and fragmentation degree. Natural Hazards and Earth System Science 5(5):621–632CrossRef

Jibson RW, Harp EL, Michael JA (2000) A method for producing digital probabilistic seismic landslide hazard maps. Eng Geol 58(3):271–289CrossRef

Keefer DK (1984) Landslides caused by earthquakes. Geol Soc Am Bull 95(4):406–421CrossRef

Lari S, Frattini P, Crosta GB (2014) A probabilistic approach for landslide hazard analysis. Eng Geol 182:3–14CrossRef

Lee S, Sambath T (2006) Landslide susceptibility mapping in the Damrei Romel area, Cambodia using frequency ratio and logistic regression models. Environ Geol 50(6):847–855CrossRef

Lee S, Ryu JH, Won JS, Park HJ (2004) Determination and application of the weights for landslide susceptibility mapping using an artificial neural network. Eng Geol 71(3):289–302CrossRef

Lee S, Ryu JH, Lee MJ, Won JS (2006) The application of artificial neural networks to landslide susceptibility mapping at Janghung, Korea. Math Geol 38(2):199–220CrossRef

Lee CT, Huang CC, Lee JF, Pan KL, Lin ML, Dong JJ (2008) Statistical approach to earthquake-induced landslide susceptibility. Eng Geol 100(1):43–58CrossRef

Mahdavifar MR, Solaymani S, Jafari MK (2006) Landslides triggered by the Avaj, Iran earthquake of June 22, 2002. Eng Geol 86(2):166–182CrossRef

Mahdavifar M, Askari F, Memarian P, Seyedimorad SM (2016) Earthquake-induced rock fall hazard zonation of Varzegha-Ahar region in Northwest Iran: a comparison of quantitative and qualitative approaches. Journal of Seismology and Earthquake Engineering 18(2):101–116

Marzorati S, Luzi L, De Amicis M (2002) Rock falls induced by earthquakes: a statistical approach. Soil Dyn Earthq Eng 22(7):565–577CrossRef

Massey CI, MacSaveney MJ, Richards L (2015) Characteristics of some Rockfalls triggered by the 2010/2011 Canterbury earthquake sequence, New Zealand. Engineering Geology for Society and Territorym, Springer 2:1943–1948

Mathew J, Jha VK, Rawat GS (2009) Landslide susceptibility zonation mapping and its validation in part of Garhwal lesser Himalaya, India, using binary logistic regression analysis and receiver operating characteristic curve method. Landslides 6(1):17–26CrossRef

Menhaj MB (2003) Basics of artificial networks: computation intelligence. Amir Kabir University press, [in Persian], 716 pp

Miles SB, Keefer DK (2009a) Evaluation of CAMEL—comprehensive areal model of earthquake-induced landslides. Eng Geol 104(1):1–15CrossRef

Miles SB, Keefer DK (2009b) Toward a comprehensive areal model of earthquake-induced landslides. Natural hazards review 10(1):19–28CrossRef

Mohammady M, Pourghasemi HR, Pradhan B (2012) Landslide susceptibility mapping at Golestan Province, Iran: a comparison between frequency ratio, Dempster–Shafer, and weights-of-evidence models. J Asian Earth Sci 61:221–236CrossRef

Motamedi M, Liang RY (2014) Probabilistic landslide hazard assessment using copula modeling technique. Landslides 11(4):565–573CrossRef

Nefeslioglu HA, Gokceoglu C, Sonmez H (2008) An assessment on the use of logistic regression and artificial neural networks with different sampling strategies for the preparation of landslide susceptibility maps. Eng Geol 97(3):171–191CrossRef

Norusis MJ (1994) SPSS Advanced Statistics 6.1. SPSS Company, Chicago 606 pp

Peng WF, Wang CL, Chen ST, Lee ST (2009) Incorporating the effects of topographic amplification and sliding areas in the modeling of earthquake-induced landslide hazards, using the cumulative displacement method. Comput Geosci 35(5):946–966CrossRef

Petley DN (2012) Landslides and engineered slopes: protecting society through improved understanding. Landslides and engineered slopes 1:3–13

Pourghasemi HR, Pradhan B, Gokceoglu C, Moezzi KD (2012a) Landslide susceptibility mapping using a spatial multi criteria evaluation model at Haraz watershed, Iran. In: Terrigenous mass movements. Springer, Berlin, pp 23–49CrossRef

Pourghasemi HR, Pradhan B, Gokceoglu C (2012b) Application of fuzzy logic and analytical hierarchy process (AHP) to landslide susceptibility mapping at Haraz watershed, Iran. Nat Hazards 63(2):965–996CrossRef

Pourghasemi HR, Mohammady M, Pradhan B (2012c) Landslide susceptibility mapping using index of entropy and conditional probability models in GIS: Safarood Basin, Iran. Catena 97:71–84CrossRef

Pourghasemi H, Pradhan B, Gokceoglu C, Moezzi KD (2013) A comparative assessment of prediction capabilities of Dempster–Shafer and weights-of-evidence models in landslide susceptibility mapping using GIS. Geomatics, Natural Hazards and Risk 4(2):93–118CrossRef

Pradhan B (2013) A comparative study on the predictive ability of the decision tree, support vector machine and neuro-fuzzy models in landslide susceptibility mapping using GIS. Comput Geosci 51:350–365CrossRef

Rapolla A, Paoletti V, Secomandi M (2010) Seismically-induced landslide susceptibility evaluation: application of a new procedure to the island of ischia, Campania region, southern Italy. Eng Geol 114(1):10–25CrossRef

Regmi NR, Giardino JR, McDonald EV, Vitek JD (2014) A comparison of logistic regression-based models of susceptibility to landslides in western Colorado, USA. Landslides 11(2):247–262CrossRef

Rodrıguez CE, Bommer JJ, Chandler RJ (1999) Earthquake-induced landslides: 1980–1997. Soil Dyn Earthq Eng 18(5):325–346CrossRef

Shariat Jafari M (2009) Specific risk zonation of landslides in the critical (Central Alborz) zones. National Disaster Mitigation Organization. A specialized workshop of earthquake and landslide, [in Persian], 95 pp

Shroder JF (2015) Landslide hazards, risks, and disasters. Elsevier Academic Press, 475 pp

Solaymani S, Feghhi K (2003) Report of Surface Faulting and Morphotectonics of Avaj Region Earthquake on June 22, 2002. International Institute of Earthquake Engineering and Seismology, [in Persian], 1–11

Straub D, Schubert M (2008) Modeling and managing uncertainties in rock-fall hazards. Georisk 2(1):1–15

Swets JA (1988) Measuring the accuracy of diagnostic systems. Science 240(4857):1285–1293CrossRef

Tchalenko JS (1974) Materials for the study of seismotectonics of Iran: North-Central Iran (No. 29). Geological Survey of Iran

Turner AK, Jayaprakash GP (2012) Introduction. Rockfall characterization and control. Transportation Research Board. National Academy of Sciences, Washington D.C., pp 3–20

Uchida T, Osanai N, Onoda S, Takayama T, Tomura K (2006) A simple method for producing probabilistic seismic shallow landslide hazard maps. In Proceedings of Interpraevent, Universal Academy Press. 2, 529–534

Valagussa A, Frattini P, Crosta GB (2014a) Quantitative probabilistic hazard analysis of earthquake-induced rockfalls. In: Landslide Science for a Safer Geoenvironment, Springer, 213–218

Valagussa A, Frattini P, Crosta GB (2014b) Earthquake-induced rockfall hazard zoning. Eng Geol 182:213–225CrossRef

Varnes DJ (1978) Slope movement types and processes. Special report 176:11–33

Wasowski J, Del Gaudio V (2000) Evaluating seismically induced mass movement hazard in Caramanico Terme (Italy). Eng Geol 58(3):291–311CrossRef

Wyllie DC (2014) Rock fall engineering. CRC Press, 270 pp

Yesilnacar EK (2005) The Application of Computational Intelligence to Landslide Susceptibility Mapping in Turkey, Ph.D Thesis. Department of Geomatics the University of Melbourne, 423pp

Yilmaz I (2009) Landslide susceptibility mapping using frequency ratio, logistic regression, artificial neural networks and their comparison: a case study from Kat landslides (Tokat—Turkey). Comput Geosci 35(6):1125–1138CrossRef

Yin KL, Yan TZ (1988) Statistical prediction model for slope instability of metamorphosed rocks. In: Proceedings of the 5th international symposium on landslides, Lausanne, Switzerland, AA Balkema Rotterdam, The Netherlands. 2, 1269–1272

Titel: Predicting the probability of rockfalls occurrence caused by the earthquake of Changureh-Avaj in 2002 using LR, MLP, and RBF methods
verfasst von: V. Bagheri
A. Uromeihy
S. M. Fatemi Aghda
Publikationsdatum: 22.06.2018
Verlag: Springer Berlin Heidelberg
Erschienen in: Bulletin of Engineering Geology and the Environment / Ausgabe 5/2019
Print ISSN: 1435-9529
Elektronische ISSN: 1435-9537
DOI: https://doi.org/10.1007/s10064-018-1323-5

Springer Professional

Abstract

Bitte loggen Sie sich ein, um Zugang zu Ihrer Lizenz zu erhalten.

Sie haben noch keine Lizenz? Dann Informieren Sie sich jetzt über unsere Produkte:

Springer Professional "Technik"

Springer Professional "Wirtschaft+Technik"

Weitere Artikel der Ausgabe 5/2019

Auscultation géologique, géophysique et géotechnique du site du barrage de Tabellout, Nord-Est Algérien

Deformations of loess soils caused by changes in the microaggregate structure

The effects of mining subsidence and drainage improvements on a waterlogged area

The influence of temperature and time on water-rock interactions based on the morphology of rock joint surfaces

Complex rock slope deformation at Laxiwa Hydropower Station, China: background, characterization, and mechanism

Numerical modelling of the long runout character of 2015 Shenzhen landslide with a general two-phase mass flow model