Deep Neural Networks for the Estimation of Masonry Structures Failures under Rockfalls

Although the principal aim of the rockfall management is to prevent rock boulders from reaching the buildings instead of the buildings resisting the boulder impacts, there usually exists a residual risk that has to be assessed, even when structural protection measurements are taken. The evaluation o...

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Published in:Geosciences (Basel) 2023-06, Vol.13 (6), p.156
Main Authors: Mavrouli, Olga, Skentou, Athanasia D., Carbonell, Josep Maria, Tsoukalas, Markos Z., Núñez-Andrés, M. Amparo, Asteris, Panagiotis G.
Format: Article
Language:English
Subjects:
Algorithms
Artificial intelligence
Artificial neural networks
Boulders
Building damage
Buildings
Concrete
Cost analysis
Earth science
Earthquakes
Empirical analysis
failure
Finite element method
Graphs
Impact damage
Landslides & mudslides
machine learning
Masonry
masonry structures
Mathematical models
Methods
Neural networks
Numerical analysis
Numerical methods
Optimization
optimization algorithms
Reinforced concrete
Risk analysis
Risk assessment
Risk management
Rock
Rock falls
Rockfall
rockfalls
Rocks
Rockslides
Safety and security measures
Seismic engineering
Tensile strength
Vulnerability
Walls
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creator Mavrouli, Olga
Skentou, Athanasia D.
Carbonell, Josep Maria
Tsoukalas, Markos Z.
Núñez-Andrés, M. Amparo
Asteris, Panagiotis G.
description Although the principal aim of the rockfall management is to prevent rock boulders from reaching the buildings instead of the buildings resisting the boulder impacts, there usually exists a residual risk that has to be assessed, even when structural protection measurements are taken. The evaluation of the expected damage of buildings due to rockfalls using empirical data from past events is not always possible, as transferring and applying damage observations from one area to another can be unrealistic. In order to simulate potential rockfall scenarios and their damage on buildings, numerical methods can be an alternative. However due to their increased requirements in expertise and computational costs, their integration into the risk analysis is limited, and simpler tools to assess the rockfall vulnerability of buildings are needed. This paper focuses on the application of artificial intelligence AI methods for providing the expected damage of masonry walls which are subjected to rockfall impacts. First, a damage database with 672 datasets was created numerically using the particle finite element method and the finite element method. The input variables are the rock volume (VR), the rock velocity (RV), the masonry wall (t) and the masonry tensile strength fm. The output variable is a damage index (DI) equal to the percentage of the damaged wall area. Different AI algorithms were investigated and the ANN LM 4-21-1 model was selected to optimally assess the expected wall damage. The optimum model is provided here (a) as an analytical equation and (b) in the form of contour graphs, mapping the DI value. Known the VR and the RV, the DI can be directly used as an input for the vulnerability of masonry walls into the quantitative rockfall risk assessment equation.
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subjects Algorithms
Artificial intelligence
Artificial neural networks
Boulders
Building damage
Buildings
Concrete
Cost analysis
Earth science
Earthquakes
Empirical analysis
failure
Finite element method
Graphs
Impact damage
Landslides & mudslides
machine learning
Masonry
masonry structures
Mathematical models
Methods
Neural networks
Numerical analysis
Numerical methods
Optimization
optimization algorithms
Reinforced concrete
Risk analysis
Risk assessment
Risk management
Rock
Rock falls
Rockfall
rockfalls
Rocks
Rockslides
Safety and security measures
Seismic engineering
Tensile strength
Vulnerability
Walls
title Deep Neural Networks for the Estimation of Masonry Structures Failures under Rockfalls
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