Intelligent Computational Paradigms in Earthquake Engineering

Intelligent Computational Paradigms in Earthquake Engineering

Nikos Lagaros, Yiannis Tsompanakis

Copyright: © 2007 |Pages: 444

ISBN13: 9781599040998|ISBN10: 1599040999|EISBN13: 9781599041018|ISBN13 Softcover: 9781599041001

DOI: 10.4018/978-1-59904-099-8

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MLA

Lagaros, Nikos, and Yiannis Tsompanakis, editors. Intelligent Computational Paradigms in Earthquake Engineering. IGI Global, 2007. https://doi.org/10.4018/978-1-59904-099-8

APA

Lagaros, N. & Tsompanakis, Y. (Eds.). (2007). Intelligent Computational Paradigms in Earthquake Engineering. IGI Global. https://doi.org/10.4018/978-1-59904-099-8

Chicago

Lagaros, Nikos, and Yiannis Tsompanakis, eds. Intelligent Computational Paradigms in Earthquake Engineering. Hershey, PA: IGI Global, 2007. https://doi.org/10.4018/978-1-59904-099-8

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The enormous advances in computational hardware and software resources over the last fifteen years resulted in the development of non-conventional data processing and simulation methods. Among these methods artificial intelligence (AI) has been mentioned as one of the most eminent approaches to the so-called intelligent methods of information processing that present a great potential for engineering applications.

Intelligent Computational Paradigms in Earthquake Engineering contains contributions that cover a wide spectrum of very important real-world engineering problems, and explore the implementation of neural networks for the representation of structural responses in earthquake engineering. This book assesses the efficiency of seismic design procedures and describes the latest findings in intelligent optimal control systems and their applications in structural engineering. Intelligent Computational Paradigms in Earthquake Engineering presents the application of learning machines, artificial neural networks and support vector machines as highly-efficient pattern recognition tools for structural damage detection. It includes an AI-based evaluation of bridge structures using life-cycle cost principles that considers seismic risk, and emphasizes the use of AI methodologies in a geotechnical earthquake engineering application.

Table of Contents

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Front Materials

Title Page

Copyright Page

Foreword

Preface

Acknowledgments

Chapters

Structural Optimization Applications

Chapter 1

Improved Seismic Design Procedures and Evolutionary Tools (pages 1-21)

Michalis Fragiadakis, Nikos D. Lagaros, Yiannis Tsompanakis, Manolis Papadrakakis

Four alternative analytical procedures are recommended by the design codes for the structural analysis of buildings under earthquake loading. The objective of this chapter is to assess these procedures by integrating them in the...

Chapter 2

Applying Neural Networks for Performance-Based Design in Earthquake Engineering (pages 22-41)

Ricardo O. Foschi

This chapter discusses the application of neural networks for the representation of structural responses in earthquake engineering, and their subsequent use in reliability evaluation and optimization for performance-based design. An...

Chapter 3

Evolutionary Seismic Design for Optimal Performance (pages 42-58)

Arzhang Alimoradi, Shahram Pezeshk, Christopher Foley

The chapter provides an overview of optimal structural design procedures for seismic performance. Structural analysis and design for earthquake effects is an evolving area of science; many design philosophies and concepts have been...

Chapter 4

Optimal Reliability-Based Design Using Support Vector Machines and Artificial Life Algorithms (pages 59-79)

Jorge Hurtado

Reliability-based optimization is considered by many authors as the most rigorous approach to structural design, because the search for the optimal solution is performed with consideration of the uncertainties present in the...

Chapter 5

Optimum Design of Structures for Earthquake Induced Loading by Wavelet Neural Network (pages 80-100)

Eysa Salajegheh, Ali Heidari

Optimum design of structures for earthquake induced loading is achieved by a modified genetic algorithm (MGA). Some features of the simulated annealing (SA) are used to control various parameters of the genetic algorithm (GA). To...

Chapter 6

Developments in Structural Optimization and Applications to Intelligent Structural Vibration Control (pages 101-121)

Faruque Ali, Ananth Ramaswamy

The chapter introduces developments in intelligent optimal control systems and their applications in structural engineering. It provides a good background on the subject starting with the shortcomings of conventional vibration...

Structural Assessment Applications

Chapter 7

Neuro-Fuzzy Assessment of Building Damage and Safety After an Earthquake (pages 123-157)

Martha Carreño, Omar Cardona, Alex Barbat

This chapter describes the algorithmic basis of a computational intelligence technique, based on a neuro-fuzzy system, developed with the objective of assisting nonexpert professionals of building construction to evaluate the damage...

Chapter 8

Learning Machines for Structural Damage Detection (pages 158-187)

Miguel Hernandez-Garcia, Mauricio Sanchez-Silva

The complexity of civil infrastructure systems and the need to keep essential systems operating after unexpected events such as earthquakes demands the development of reliable health monitoring techniques to detect the existence...

Chapter 9

Structural Assessment of RC Constructions and Fuzzy Expert Systems (pages 188-230)

Mauro Mezzina, Giuseppina Uva, Rita Greco, Giuseppe Acciani, Giuseppe Cascella, Girolamo Fornarelli

The chapter deals with the structural assessment of existing constructions, with a particular attention to seismic risk mitigation. Two aspects are involved: the appraisal of the actual conditions of the structure (material...

Chapter 10

Life-Cycle Cost Evaluation of Bridge Structures Considering Seismic Risk (pages 231-247)

Hitoshi Furuta, Kazuhiro Koyama

This chapter introduces a life-cycle cost (LCC) analysis of bridge structures considering seismic risk. Recently, LCC has been paid attention as a possible and promising method to achieve a rational maintenance program. In general...

Chapter 11

Soft Computing Techniques in Probabilistic Seismic Analysis of Structures (pages 248-269)

Nikos Lagaros, Yiannis Tsompanakis, Michalis Fragiadakis, Manolis Papadrakakis

Earthquake-resistant design of structures using probabilistic analysis is an emerging field in structural engineering. The objective of this chapter is to investigate the efficiency of soft computing methods when incorporated into...

Structural Identification Applications

Chapter 12

Inverse Analysis of Weak and Strong Motion Downhole Array Data: A Hybrid Optimization Algorithm (pages 271-315)

Dominic Assimaki

A seismic waveform inversion algorithm is proposed for the estimation of elastic soil properties using low amplitude, downhole array recordings. Based on a global optimization scheme in the wavelet domain, complemented by a local...

Chapter 13

Genetic Algorithms in Structural Identification and Damage Detection (pages 316-341)

Chan Koh

Genetic algorithms (GA) have proved to be a robust, efficient search technique for many problems. In this chapter, the latest developments by the authors in the area of structural identification and structural damage detection using...

Chapter 14

Neural Network-Based Identification of Structural Parameters in Multistory Buildings (pages 342-361)

Snehashish Chakraverty

A detailed study of the capabilities and powerfulness of soft computing techniques such as artificial neural network with respect to the identification of structural parameters and structural responses are presented. This chapter...

Chapter 15

Application of Neurocomputing to Parametric Identification Using Dynamic Responses (pages 362-392)

Leonard Ziemianski, Bartosz Miller, Grzegorz Piatkowski

The chapter focuses on the applications of neurocomputing to the analysis of identification problems in structural dynamics, the main attention is paid to back-propagation neural networks. The analysed problems relate to (a)...

Chapter 16

Neural Networks for the Simulation and Identification Analysis of Buildings Subjected to Paraseismic Excitations (pages 393-432)

Krystyna Kuzniar, Zenon Waszczyszyn

The chapter deals with an application of neural networks to the analysis of vibrations of medium-height prefabricated buildings with load-bearing walls subjected to paraseismic excitations. Neural network technique was used for...

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