2019
DOI: 10.1007/s12517-018-4162-6
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Predictive modeling of static and seismic stability of small homogeneous earth dams using artificial neural network

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Cited by 12 publications
(4 citation statements)
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“…Artificial neural networks are often divided into two categories: one is a recursive network that generates loops through feedback connections, and the other is a feedforward neural network [22] in which the network structure has no loops. The typical single hidden layer feedforward neural network structure is shown in Figure 1.…”
Section: Backpropagation Neural Networkmentioning
confidence: 99%
“…Artificial neural networks are often divided into two categories: one is a recursive network that generates loops through feedback connections, and the other is a feedforward neural network [22] in which the network structure has no loops. The typical single hidden layer feedforward neural network structure is shown in Figure 1.…”
Section: Backpropagation Neural Networkmentioning
confidence: 99%
“…Fattahi [13] utilized different ANFIS models (grid partitioning, subtractive clustering, and fuzzy cmeans clustering) to assess their ability for the estimation of FOS. Zeroual et al [14] used the ANN to develop a prediction model for the FOS estimation of earth dams. Haghshenas et al [15] developed a hybrid algorithm using Harmony search and the K-means algorithm to analyze the slope stability based on a limited database made up of 19 case studies.…”
Section: Introductionmentioning
confidence: 99%
“…Arti cial neural networks (ANN) for structural reliability analysis have been used since 1989 when Hornik et al [16][17][18] proved that multilayer networks can approximate any function with a high degree of accuracy. Some other applications are as follows: Chen [19][20][21] uses genetic algorithms to calculate the reliability index of bridges, trusses, and at frames; Bojorquez et al [22] propose a methodology based on optimization to nd live, dead, and earthquake load factors for design of buildings located on soft soil; Dai and Cao [23] use hybrid methods (ANN and wavelet neural network) to obtain the probability of failure of various structures; Santana Gomes [18] calculates the probability of failure of several structures using adaptive ANN and compares its results obtained with these networks with those from Monte Carlo simulations; Wen et al [24] optimize ANN to obtain the reliability of gas lines and compare their results with an unoptimized network and with Monte Carlo simulations; however, there are very few studies focused on the use of artificial intelligence for the calculation of structural safety factors; for example, Koopialipoor [25] uses the ant colony optimization algorithm to maximize the safety factor of retaining walls; Zeroual [26] calculates safety factors for dams, using a feedforward backpropagation network; Gordan et al [27] obtain safety factors for retaining walls using ANN and "artificial bee colony"; and Zhang et al [28] propose a Bayesian network for calculating pile resistance factors.…”
Section: Introductionmentioning
confidence: 99%