nach oben

Environmental Earth Sciences

Erschienen in:

01.04.2017 | Original Article

A comparative study of landslide susceptibility mapping using weight of evidence, logistic regression and support vector machine and evaluated by SBAS-InSAR monitoring: Zhouqu to Wudu segment in Bailong River Basin, China

verfasst von: Zhengtuan Xie, Guan Chen, Xingmin Meng, Yi Zhang, Liang Qiao, Long Tan

Erschienen in: Environmental Earth Sciences | Ausgabe 8/2017

Einloggen

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

search-config

KI-gestützte Suche

Aus

Abstract

The determining of landslide-prone areas in mountainous terrain is essential for land planning and hazard mitigation. In this paper, a comparative study using three statistical models including weight of evidence model (WoE), logistic regression model (LR) and support vector machine method (SVM) was undertaken in the Zhouqu to Wudu segment in the Bailong River Basin, Southern Gansu, China. Six conditionally independent environmental factors, elevation, slope, aspect, distance from fault, lithology and settlement density, were selected as the explanatory variables that may contribute to landslide occurrence based on principal component analysis (PCA) and Chi-square test. The relation between landslide distributions and these variables was analyzed using the three models and the results then used to calculate the landslide susceptibility (LS). The performance of the models was then evaluated using both the highly accurate deformation signals produced by using the Small Baseline Subset Interferometric Synthetic Aperture Radar technique and Receiver Operating Characteristic (ROC) curve. Results show more deformation points in areas with high and very high LS levels, and also more stable points in areas with low and very low LS levels for the SVM model. In addition, the SVM has larger area under the ROC curve. It indicates that the SVM has better prediction accuracy and classified ability. For the interpretability, the WoE derives the class of factors that most contributed to landsliding in the study area, and the LR reveals that factors including elevation, settlement density and distance from fault played major roles in landslide occurrence and distribution, whereas the SVM cannot provide relative weights for the variables. The outperformed SVM could be employed to determine potential landslide zones in the study area. Outcome of this research would provide preliminary basis for general land planning such as choosing new urban areas and infrastructure construction in the future, as well as for landslide hazard mitigation in Bailong River Basin.

Vorheriger Artikel Application of inverse modeling in a study of the hydrogeochemical evolution of karst groundwater in the Jinci Spring region, northern China

Nächster Artikel Assessment of arsenic and fluoride pollution in groundwater in Dawukou area, Northwest China, and the associated health risk for inhabitants

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

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

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

Akgun A (2012) A comparison of landslide susceptibility maps produced by logistic regression, multi-criteria decision, and likelihood ratio methods: a case study at İzmir, Turkey. Landslides 9(1):93–106CrossRef

Allison PD (2001) Logistic regression using SAS System: theory and application. Wiley Interscience, New York

Arora M, Das Gupta A, Gupta R (2004) An artificial neural network approach for landslide hazard zonation in the Bhagirathi (Ganga) Valley, Himalayas. Int J Remote Sens 25(3):559–572CrossRef

Atkinson P, Massari R (1998) Generalised linear modelling of susceptibility to landsliding in the central Apennines, Italy. Comput Geosci 24(4):373–385CrossRef

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

Bai SB, Wang J, Lü GN, Zhou PG, Hou SS, Xu SN (2010) GIS-based logistic regression for landslide susceptibility mapping of the Zhongxian segment in the Three Gorges area, China. Geomorphology 115(1):23–31CrossRef

Bai S, Wang J, Zhang Z, Cheng C (2012) Combined landslide susceptibility mapping after Wenchuan earthquake at the Zhouqu segment in the Bailongjiang Basin, China. CATENA 99(4):18–25CrossRef

Bai S, Wang J, Thiebes B, Cheng C, Yang Y (2013) Analysis of the relationship of landslide occurrence with rainfall: a case study of wudu county, china. Arab J Geosci 7(4):1277–1285CrossRef

Bonham-Carter GF (1994) Geographic information systems for geoscientists: modelling with GIS, 13. Computer methods in the geosciences. Pergamon Press, New York, p 414

Brenning A (2005) Spatial prediction models for landslide hazards: review, comparison and evaluation. Nat Hazards Earth Syst Sci 5(6):853–862CrossRef

Carrara A, Cardinali M, Guzzetti F, Reichenbach P (1995) GIS technology in mapping landslide hazard. In: Carrara A, Guzzetti F (eds) Geographical information systems in assessing natural hazards. Kluwer, Dordrecht, pp 135–176CrossRef

Chacón J, Irigaray C, Fernández T, Hamdouni RE (2006) Engineering geology maps: landslides and geographical information systems. Bull Eng Geol Envron 65(4):341–411CrossRef

Chen WW, Zhao ZF, Liu G, Liang SY (2006) The engineering geological problems study of Gansu section of Lanzhou–Haikou highway. Lanzhou University Press, Lanzhou (in Chinese)

Chen G, Meng X, Tan L, Zhang F, Qiao L (2014) Comparison and combination of different models for optimal landslide susceptibility zonation. Q J Eng GeolHydrogeol 47(4):283–306CrossRef

Chung CJ (2006) Using likelihood ratio functions for modeling the conditional probability of occurrence of future landslides for risk assessment. Comput Geosci 32(8):1052–1068CrossRef

Chung CJF, Fabbri AG (2003) Validation of spatial prediction models for landslide hazard mapping. Nat Hazards 30(3):451–472CrossRef

Colombo A, Mallen L, Pispico R, Giannico C, Bianchi M and Savio G (2006) Mappatura regionale delle aree monitorabili mediante l’uso della tecnica PS. Proceedings of National Conference ASITA, Bolzano, Italy, pp 14–17

Cui P, Zhou GG, Zhu X, Zhang J (2013) Scale amplification of natural debris flows caused by cascading landslide dam failures. Geomorphology 182(427):173–189CrossRef

Dai F, Lee C (2002) Landslide characteristics and slope instability modeling using GIS, Lantau Island, Hong Kong. Geomorphology 42(3):213–228CrossRef

Derbyshire E, Meng X, Dijkstra TA (2000) Landslides in the thick loess terrain of North-West China. Wiley, Chichester, pp 1–256

Greco R, Sorriso-Valvo M, Catalano E (2007) Logistic regression analysis in the evaluation of mass movements susceptibility: the Aspromonte case study, Calabria, Italy. Eng Geol 89(1):47–66CrossRef

Guzzetti F, Carrara A, Cardinali M, Reichenbach P (1999) Landslide hazard evaluation: a review of current techniques and their application in a multi-scale study, Central Italy. Geomorphology 31(1):181–216CrossRef

Hong H, Pourghasemi HR, Pourtaghi ZS (2016) Landslide susceptibility assessment in lianhua county (china): a comparison between a random forest data mining technique and bivariate and multivariate statistical models. Geomorphology 259:105–118CrossRef

Hosmer DW, Lemeshow S (1989) Applied regression analysis. Wiley, New York, p 307

Kavzoglu T, Sahin EK, Colkesen I (2014) Landslide susceptibility mapping using GIS-based multi-criteria decision analysis, support vector machines, and logistic regression. Landslides 11(3):425–439CrossRef

Kayastha P, Dhital MR, De Smedt F (2012) Landslide susceptibility mapping using the weight of evidence method in the Tinau watershed, Nepal. Nat Hazards 63(2):479–498CrossRef

Keefer DK, Larsen MC (2007) Assessing landslide hazards. Science(Washington) 316(5828):1136–1138CrossRef

Kincal C, Singleton A, Li Z, Drummond J, Hoey T, Muller J, Qu W, Zeng Q, Zhang J, Du P (2010) Mass movement susceptibility mapping using satellite optical imagery compared with insar monitoring: Zigui county, three gorges region, China. Dragon-2 Symposium

Lee S (2004) Application of likelihood ratio and logistic regression models to landslide susceptibility mapping using GIS. Environ Manag 34(2):223–232CrossRef

Lu D, Cui J, Li X, Lian W (2010) Ground motion attenuation of M S8. 0 Wenchuan earthquake. Earthq Sci 23(1):95–100CrossRef

Lu P, Catani F, Tofani V, Casagli N (2014) Quantitative hazard and risk assessment for slow-moving landslides from persistent scatterer interferometry. Landslides 11(4):685–696CrossRef

Marjanović M, Kovačević M, Bajat B, Voženílek V (2011) Landslide susceptibility assessment using SVM machine learning algorithm. Eng Geol 123(3):225–234CrossRef

Meisina C, Zucca F, Notti D, Colombo A, Cucchi A, Savio G, Giannico C, Bianchi M (2008) Geological interpretation of PSInSAR data at regional scale. Sensors 8(11):7469–7492CrossRef

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(15):221–236CrossRef

Nandi A, Shakoor A (2010) A GIS-based landslide susceptibility evaluation using bivariate and multivariate statistical analyses. Eng Geol 110(1):11–20CrossRef

Oh HJ, Lee S (2010) Assessment of ground subsidence using GIS and the weights-of-evidence model. Eng Geol 115(1):36–48CrossRef

Ozdemir A, Altural T (2013) A comparative study of frequency ratio, weights of evidence and logistic regression methods for landslide susceptibility mapping: Sultan Mountains, SW Turkey. J Asian Earth Sci 64(5):180–197CrossRef

Paulín GL, Pouget S, Bursik M, Quesada FA, Contreras T (2016) Comparing landslide susceptibility models in the río el estado watershed on the sw flank of pico de orizaba volcano, mexico. Nat Hazards 80(1):127–139CrossRef

Peng L, Niu R, Huang B, Wu X, Zhao Y, Ye R (2014) Landslide susceptibility mapping based on rough set theory and support vector machines: a case of the Three Gorges area, China. Geomorphology 204(1):287–301CrossRef

Pourghasemi HR, Jirandeh AG, Pradhan B, Xu C, Gokceoglu C (2013) Landslide susceptibility mapping using support vector machine and GIS at the Golestan Province, Iran. J Earth Syst Sci 122(2):349–369CrossRef

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(2):350–365CrossRef

Regmi NR, Giardino JR, Vitek JD (2010) Modeling susceptibility to landslides using the weight of evidence approach: western Colorado, UA. Geomorphology 115(1):172–187CrossRef

Santacana N, Baeza B, Corominas J, De Paz A, Marturiá J (2003) A GIS-based multivariate statistical analysis for shallow landslide susceptibility mapping in La Pobla de Lillet Area (Eastern Pyrenees, Spain). Nat Hazards 30(3):281–295CrossRef

Schicker R, Moon V (2012) Comparison of bivariate and multivariate statistical approaches in landslide susceptibility mapping at a regional scale. Geomorphology 161–162(7):40–57CrossRef

Singh LP, Van Westen C, Ray PC, Pasquali P (2005) Accuracy assessment of insar derived input maps for landslide susceptibility analysis: a case study from the swiss alps. Landslides 2(3):221–228CrossRef

Soeters R, van Westen CJ (1996) Slope instability recognition, analysis and zonation. In: Turner AK, Schuster RL (eds) Landslides, investigation and mitigation. Transportation Research Board, National Research Council, Special Report 247. National Academy Press, Washington, pp 129–177

Süzen ML, Doyuran V (2004) A comparison of the GIS based landslide susceptibility assessment methods: multivariate versus bivariate. Environ Geol 45(5):665–679CrossRef

Tax DM, Duin RP (2002) Uniform object generation for optimizing one-class classifiers. J Mach Learn Res 2(2):155–173

Thiery Y, Malet J-P, Sterlacchini S, Puissant A, Maquaire O (2007) Landslide susceptibility assessment by bivariate methods at large scales: application to a complex mountainous environment. Geomorphology 92(1):38–59CrossRef

Tizzani P, Berardino P, Casu F, Euillades P, Manzo M, Ricciardi GP, Zeni G, Lanari R (2007) Surface deformation of long valley caldera and mono basin, california, investigated with the SBAS-InSAR approach. Remote Sens Environ 108(3):277–289CrossRef

Van Westen C, Rengers N, Soeters R (2003) Use of geomorphological information in indirect landslide susceptibility assessment. Nat Hazards 30(3):399–419CrossRef

Van Westen C, Van Asch TW, Soeters R (2006) Landslide hazard and risk zonation—why is it still so difficult? Bull Eng Geol Env 65(2):167–184CrossRef

Vapink VN (1995) The nature of statistical learning theory. Springer, New YorkCrossRef

Varnes D (1984) International Association of Engineering Geology Commission on Landslides and Other Mass Movements on Slopes. Landslide Hazard Zonation: A Review of Principles and Practice: Int Assoc Eng Geol, UNESCO Natural Hazards Series, No. 3. P 63

Xu C, Dai F, Xu X, Lee YH (2012) GIS-based support vector machine modeling of earthquake-triggered landslide susceptibility in the Jianjiang River watershed, China. Geomorphology 145–146(2):70–80CrossRef

Xu C, Xu X, Yao Q, Wang Y (2013) GIS-based bivariate statistical modelling for earthquake-triggered landslides susceptibility mapping related to the 2008 Wenchuan earthquake, China. Q J Eng Geol Hydrogeol 46(2):221–236CrossRef

Yalcin A (2008) GIS-based landslide susceptibility mapping using analytical hierarchy process and bivariate statistics in Ardesen (Turkey): comparisons of results and confirmations. CATENA 72(1):1–12CrossRef

Yalcin A, Reis S, Aydinoglu A, Yomralioglu T (2011) A GIS-based comparative study of frequency ratio, analytical hierarchy process, bivariate statistics and logistics regression methods for landslide susceptibility mapping in Trabzon, NE Turkey. CATENA 85(3):274–287CrossRef

Yao X, Tham L, Dai F (2008) Landslide susceptibility mapping based on support vector machine a case study on natural slopes of Hong Kong, China. Geomorphology 101(4):572–582CrossRef

Yilmaz I (2010) Comparison of landslide susceptibility mapping methodologies for Koyulhisar, Turkey: conditional probability, logistic regression, artificial neural networks, and support vector machine. Environ Earth Sci 61(4):821–836CrossRef

Youssef AM, Pourghasemi HR, Pourtaghi ZS, Al-Katheeri MM (2016) 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. Landslides 13(5):839–856CrossRef

Yu B, Yang Y, Su Y, Huang W, Wang G (2010) Research on the giant debris flow hazards in Zhouqu County, Gansu Province on August 7, 2010. J Eng Geol 18(4):437–444 (in Chinese)

Zhang Y, Meng X, Chen G, Qiao L, Zeng R, Chang J (2016) Detection of geohazards in the bailong river basin using synthetic aperture radar interferometry. Landslides 13(5):1273–1284CrossRef

Titel: A comparative study of landslide susceptibility mapping using weight of evidence, logistic regression and support vector machine and evaluated by SBAS-InSAR monitoring: Zhouqu to Wudu segment in Bailong River Basin, China
verfasst von: Zhengtuan Xie
Guan Chen
Xingmin Meng
Yi Zhang
Liang Qiao
Long Tan
Publikationsdatum: 01.04.2017
Verlag: Springer Berlin Heidelberg
Erschienen in: Environmental Earth Sciences / Ausgabe 8/2017
Print ISSN: 1866-6280
Elektronische ISSN: 1866-6299
DOI: https://doi.org/10.1007/s12665-017-6640-7

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 "Wirtschaft+Technik"

Springer Professional "Technik"

Weitere Artikel der Ausgabe 8/2017

Combining a connected-component labeling algorithm with FILTERSIM to simulate continuous discrete fracture networks

Landslide susceptibility mapping in Bijar city, Kurdistan Province, Iran: a comparative study by logistic regression and AHP models

High-resolution profiles of trace metals assessed by DGT techniques in lake sediment porewaters

The human impact on the transformation of juniper forest landscape in the western part of the Pamir-Alay range (Tajikistan)

Assessment of alluvial aquifer heterogeneity and development of stochastic hydrofacies models for the Hat Yai Basin in Southern Thailand

Treatment on oil/water gel deposition behavior in non-heating gathering and transporting process with polymer flooding wells