Abstract
In this paper, we evaluate the predictive performance of an adaptive neuro-fuzzy inference system (ANFIS) using six different membership functions (MF). In combination with a geographic information system (GIS), ANFIS was used for land subsidence susceptibility mapping (LSSM) in the Marand plain, northwest Iran. This area is prone to droughts and low groundwater levels and subsequent land subsidence damages. Therefore, a land subsidence inventory database was created from an extensive field survey. Areas of land subsidence or areas showing initial signs of subsidence were used for training, while one-third of inventory database were reserved for testing and validation. The inventory database randomly divided into three different folds of the same size. One of the folds was chosen for testing and validation. Other two folds was used for training. This process repeated for every fold in the inventory dataset. Thereafter, land subsidence related factors, such as hydrological and topographical factors, were prepared as GIS layers. Areas susceptible to land subsidence were then analyzed using the ANFIS approach, and land subsidence susceptibility maps were created, whereby six different MFs were applied. Lastly, the results derived from each MF were validated with those areas of the land subsidence database that were not used for training. Receiver operating characteristics (ROC) curves were drawn for all LSSMs, and the areas under the curves were calculated. The ROC analyses for the six LSSMs yielded very high prediction values for two out of the six methods, namely the difference of DsigMF (0.958) and GaussMF (0.951). The integration of ANFIS and GIS generally led to high LSSM prediction accuracies. This study demonstrated that the choice of training dataset and the MF significantly affects the results.
Highlights
Land subsidence is the downward motion of a land surface, including rock and soil
In this paper, we evaluate the predictive performance of an adaptive neuro-fuzzy inference system (ANFIS) using six different membership functions (MF)
The study consisted of three main steps: the design and structuring of the ANFIS model, the susceptibility mapping, and a validation step for different MFs and folds used
Summary
Land subsidence is the downward motion of a land surface, including rock and soil. This movement happens suddenly or gradually when the underground layers cannot withstand the pressure of the upper layers (Pacheco et al 2006; Ashraf and Cawood 2015). In order to map areas susceptible to natural hazards, some recent attempts have been made to utilize mathematical or statistical methods, such as artificial neural networks (ANN, Lee et al 2004, 2012; Pradhan and Lee 2010; Chen et al 2017a, b), fuzzy logic (FL, Pradhan 2011; Feizizadeh et al 2014a; Shadman Roodposhti et al 2016), support vector machine (SVM, Feizizadeh et al 2017), decision tree (DT, Lee and Park 2013), neuro-fuzzy (NF, Vahidnia et al 2010) and adaptive neuro-fuzzy inference system (ANFIS, Cam and Yildiz 2006; Oh and Pradhan 2011; Bui et al 2012; Sezer et al 2011; Basser et al 2014; Polykretis et al 2017; Chen et al 2017a, b). We will validate the maps produced for each of the MFs
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