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Environmental Earth Sciences

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01.02.2017 | Original Article

Rock fall susceptibility assessment along a mountainous road: an evaluation of bivariate statistic, analytical hierarchy process and frequency ratio

verfasst von: Ataollah Shirzadi, Kamran Chapi, Himan Shahabi, Karim Solaimani, Ataollah Kavian, Baharin Bin Ahmad

Erschienen in: Environmental Earth Sciences | Ausgabe 4/2017

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Abstract

Few studies have been conducted for susceptibility of rock falls in mountainous areas. In this study, we compare and evaluate rock fall susceptibility mapping using bivariate statistical [weight of evidence (WoE)], analytical hierarchy process (AHP) and frequency ratio (FR) methods along 11 km of a mountainous road in the Salavat Abad saddle in southwestern Kurdistan, Iran. A total of 34 rock fall locations were constructed from various sources. These rock fall locations were then partitioned into a training dataset (70% of the rock fall locations) and a testing dataset (30% of the rock fall locations). Eight conditioning factors affecting on the rock falls including slope angle, aspect, curvature, elevation, distance to road, distance to fault, lithology and land use were identified. The modeling process and rock fall susceptibility mapping has been constructed using three methods. The performance of rock fall susceptibility mapping was evaluated using the area under the curve of success rate curve for training and prediction rate curves (PRC) for testing datasets and also seed cell area index. The results show that the rock fall susceptibility mapping using the WOE method has better prediction accuracy than the AHP and FR methods. Ultimately, the weight-of-evidence method is a promising technique so that it is proposed to manage and mitigate the damages of rock falls in the prone areas.

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Agterberg FP (1992) Combining indicator patterns in weights of evidence modeling for resource evaluation. Nonrenew Resour 1:39–50CrossRef

Althuwaynee OF, Pradhan B, Park H-J, Lee JH (2014) A novel ensemble bivariate statistical evidential belief function with knowledge-based analytical hierarchy process and multivariate statistical logistic regression for landslide susceptibility mapping. Catena 114:21–36CrossRef

Ayalew L, Yamagishi H, Marui H, Kanno T (2005) Landslides in Sado Island of Japan: part II GIS-based susceptibility mapping with comparisons of results from two methods and verifications. Eng Geol 81:432–445CrossRef

Barbieri G, Cambuli P (2009) The weight of evidence statistical method in landslide susceptibility mapping of the Rio Pardu Valley (Sardinia, Italy). In: Proceedings of, 2009, pp 2658–2664

Bonham-Carter GF (1994) Geographic information systems for geoscientists-modeling with GIS. Comput Methods Geosci 13:398

Carrara A, Cardinali M, Detti R, Guzzetti F, Pasqui V, Reichenbach P (1991) GIS techniques and statistical models in evaluating landslide hazard. Earth Surf. Process Landf 16:427–445CrossRef

Chau K, Sze Y, Fung M, Wong W, Fong E, Chan L (2004) Landslide hazard analysis for Hong Kong using landslide inventory and GIS. Comput Geosci 30:429–443CrossRef

Choi J, Oh H-J, Lee H-J, Lee C, Lee S (2012) Combining landslide susceptibility maps obtained from frequency ratio, logistic regression, and artificial neural network models using ASTER images and GIS. Eng Geol 124:12–23CrossRef

Corominas J, Santacana N (2003) Stability analysis of the Vallcebre translational slide, Eastern Pyrenees (Spain) by means of a GIS. Nat Hazards 30:473–485CrossRef

Corsini A, Cervi F, Ronchetti F (2009) Weight of evidence and artificial neural networks for potential groundwater spring mapping: an application to the Mt. Modino area (Northern Apennines, Italy). Geomorphology 111:79–87CrossRef

Dai F, Lee C, Ngai YY (2002) Landslide risk assessment and management: an overview. Eng Geol 64:65–87CrossRef

D’Amato J, Hantz D, Guerin A, Jaboyedoff M, Baillet L, Mariscal A (2016) Influence of meteorological factors on rockfall occurrence in a middle mountain limestone cliff. Nat Hazards Earth Syst Sci 16:719–735CrossRef

Delonca A, Gunzburger Y, Verdel T (2014) Statistical correlation between meteorological and rockfall databases. Nat Hazards Earth Syst Sci 14:1953–1964CrossRef

Dussauge-Peisser C, Helmstetter A, Grasso J-R, Hantz D, Desvarreux P, Jeannin M, Giraud A (2002) Probabilistic approach to rock fall hazard assessment: potential of historical data analysis. Nat Hazards Earth Syst Sci 2:15–26CrossRef

Estoque RC (2012) Analytic hierarchy process in geospatial analysis. In: Murayama Y (ed) Progress in geospatial analysis. Springer, Japan, pp 157–181CrossRef

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 89:47–66CrossRef

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 31:181–216CrossRef

Hallet B (2006) Why do freezing rocks break? Science 314:1092–1093CrossRef

Hantz D, Vengeon J, Dussauge-Peisser C (2003) An historical, geomechanical and probabilistic approach to rock-fall hazard assessment. Nat Hazards Earth Syst Sci 3:693–701CrossRef

Hasekioğulları GD, Ercanoglu M (2012) A new approach to use AHP in landslide susceptibility mapping: a case study at Yenice (Karabuk, NW Turkey). Nat Hazards 63:1157–1179CrossRef

Hegg C, Kienholz H (1995) Determining paths of gravity-driven slope processes: the ‘Vector Tree Model’. In: Carrara A, Guzzetti F (eds) Geographical information systems in assessing natural hazards. Springer, Netherlands, pp 79–92CrossRef

Hungr O, Evans S (1988) Engineering evaluation of fragmental rockfall hazards. In: 5th International symposium on landslides, pp 685–690

Hussin HY, Zumpano V, Reichenbach P, Sterlacchini S, Micu M, van Westen C, Bălteanu D (2016) Different landslide sampling strategies in a grid-based bi-variate statistical susceptibility model. Geomorphology 253:508–523CrossRef

Iovine GG, Greco R, Gariano SL, Pellegrino AD, Terranova OG (2014) Shallow-landslide susceptibility in the Costa Viola mountain ridge (southern Calabria, Italy) with considerations on the role of causal factors. Nat Hazards 73:111–136CrossRef

Kayastha P, Dhital M, De Smedt F (2013) Application of the analytical hierarchy process (AHP) for landslide susceptibility mapping: a case study from the Tinau watershed, west Nepal. Comput Geosci 52:398–408CrossRef

Kelarestaghi A, Ahmadi H (2009) Landslide susceptibility analysis with a bivariate approach and GIS in Northern Iran. Arab J Geosci 2:95–101CrossRef

Keylock C, Domaas U (1999) Evaluation of topographic models of rockfall travel distance for use in hazard applications. Arct Antarct Alp Res 31:312–320CrossRef

Kıncal C, Akgun A, Koca MY (2009) Landslide susceptibility assessment in the Izmir (West Anatolia, Turkey) city center and its near vicinity by the logistic regression method. Environ Earth Sci 59:745–756CrossRef

Kirkby M, Statham I (1975) Surface stone movement and scree formation. J Geol 83:349–362CrossRef

Kobayashi Y, Harp E, Kagawa T (1990) Simulation of rockfalls triggered by earthquakes. Rock Mech Rock Eng 23:1–20CrossRef

Krautblatter M, Moser M (2009) A nonlinear model coupling rockfall and rainfall intensity based newline on a four year measurement in a high Alpine rock wall (Reintal, German Alps). Nat Hazards Earth Syst Sci 9:1425–1432CrossRef

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

Lee S (2005) Application of logistic regression model and its validation for landslide susceptibility mapping using GIS and remote sensing data. Int J Remote Sens 26:1477–1491CrossRef

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

Lu P, Rosenbaum M (2003) Artificial neural networks and grey systems for the prediction of slope stability. Nat Hazards 30:383–398CrossRef

Luckman B, Fiske C (1995) Estimating long-term rockfall accretion rates by lichenometry Steepland. Geomorphology 3:221–254

Matsuoka N, Sakai H (1999) Rockfall activity from an alpine cliff during thawing periods. Geomorphology 28:309–328CrossRef

Oh H-J, Lee S, Chotikasathien W, Kim CH, Kwon JH (2009) Predictive landslide susceptibility mapping using spatial information in the Pechabun area of Thailand. Environ Geol 57:641–651CrossRef

Ozdemir A (2011) Landslide susceptibility mapping using Bayesian approach in the Sultan Mountains (Akşehir, Turkey). Nat Hazards 59:1573–1607CrossRef

Park S, Choi C, Kim B, Kim J (2013) Landslide susceptibility mapping using frequency ratio, analytic hierarchy process, logistic regression, and artificial neural network methods at the Inje area Korea. Environ Earth Sci 68:1443–1464CrossRef

Petschko H, Brenning A, Bell R, Goetz J, Glade T (2014) Assessing the quality of landslide susceptibility maps–case study lower Austria. Nat Hazards Earth Syst Sci 14:95–118CrossRef

Pfeiffer TJ, Bowen TD (1989) Computer simulation of rockfalls. Bull Assoc Eng Geol 26:135–146

Pourtaghi ZS, Pourghasemi HR (2014) GIS-based groundwater spring potential assessment and mapping in the Birjand Township, southern Khorasan Province Iran. Hydrogeol J 22:643–662CrossRef

Pradhan B (2010) Landslide susceptibility mapping of a catchment area using frequency ratio, fuzzy logic and multivariate logistic regression approaches. J Indian Soc Remote Sens 38:301–320CrossRef

Quan H-C, Lee B-G (2012) GIS-based landslide susceptibility mapping using analytic hierarchy process and artificial neural network in Jeju (Korea). KSCE J Civ Eng 16:1258–1266CrossRef

Regmi AD, Devkota KC, Yoshida K, Pradhan B, Pourghasemi HR, Kumamoto T, Akgun A (2014) Application of frequency ratio, statistical index, and weights-of-evidence models and their comparison in landslide susceptibility mapping in Central Nepal Himalaya. Arab J Geosci 7:725–742CrossRef

Saaty TL (1977) A scaling method for priorities in hierarchical structures. J Math Psychol 15:234–281CrossRef

Saaty T (1980) The analytic hierarchy process—what it is and how it is used. Math Model 9:161–176CrossRef

Sandersen F, Bakkehøi S, Hestnes E, Lied K (1997) The influence of meteorological factors on the initiation of debris flows, rockfalls, rockslides and rockmass stability Publikasjon-Norges Geotekniske Institutt 201 pp 97–114

Shahabi H, Hashim M (2015) Landslide susceptibility mapping using GIS-based statistical models and Remote sensing data in tropical environment. Sci Rep 5. doi:10.1038/srep09899

Shahabi H, Ahmad B, Khezri S (2013) Evaluation and comparison of bivariate and multivariate statistical methods for landslide susceptibility mapping (case study: Zab basin). Arab J Geosci 6:3885–3907CrossRef

Shahabi H, Khezri S, Ahmad BB, Hashim M (2014) Landslide susceptibility mapping at central Zab basin, Iran: a comparison between analytical hierarchy process, frequency ratio and logistic regression models. Catena 115:55–70CrossRef

Shirzadi A, Saro L, Joo OH, Chapi K (2012) A GIS-based logistic regression model in rock-fall susceptibility mapping along a mountainous road: Salavat Abad case study Kurdistan, Iran. Nat Hazards 64:1639–1656CrossRef

Sturzenegger M, Sartori M, Jaboyedoff M, Stead D (2007) Regional deterministic characterization of fracture networks and its application to GIS-based rock fall risk assessment. Eng Geol 94:201–214CrossRef

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

Uribe-Etxebarria G, Morales T, Uriarte JA, Ibarra V (2005) Rock cut stability assessment in mountainous regions. Environ Geol 48:1002–1013CrossRef

Vargas LG (1990) An overview of the analytic hierarchy process and its applications. Eur J Oper Res 48:2–8CrossRef

Whalley W (1984) Rockfalls Slope instability:217-256

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

Yesilnacar E, Topal T (2005) Landslide susceptibility mapping: a comparison of logistic regression and neural networks methods in a medium scale study, Hendek region (Turkey). Eng Geol 79:251–266CrossRef

Zimmer VL, Collins BD, Stock GM, Sitar N (2012) Rock fall dynamics and deposition: an integrated analysis of the 2009 Ahwiyah Point rock fall Yosemite National Park, USA. Earth Surf Process Landf 37:680–691CrossRef

Titel: Rock fall susceptibility assessment along a mountainous road: an evaluation of bivariate statistic, analytical hierarchy process and frequency ratio
verfasst von: Ataollah Shirzadi
Kamran Chapi
Himan Shahabi
Karim Solaimani
Ataollah Kavian
Baharin Bin Ahmad
Publikationsdatum: 01.02.2017
Verlag: Springer Berlin Heidelberg
Erschienen in: Environmental Earth Sciences / Ausgabe 4/2017
Print ISSN: 1866-6280
Elektronische ISSN: 1866-6299
DOI: https://doi.org/10.1007/s12665-017-6471-6

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