Structural Health Monitoring of Civil Infrastructure Systems

Structural health monitoring is an extremely important methodology in evaluating the 'health' of a structure by assessing the level of deterioration and remaining service life of civil infrastructure systems. This book reviews key developments in research, technologies, and applications in...

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Main Authors	Karbhari, Vistasp M, Ansari, Farhad
Format	eBook
Language	English
Published	Chantilly Woodhead Publishing 2009 Elsevier Science & Technology
Edition	1
Series	Woodhead Publishing in materials
Subjects	Infrastructure Nondestructive Testing & Evaluation Structural Health Monitoring Transportation Engineering
Online Access	Get full text

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Abstract	Structural health monitoring is an extremely important methodology in evaluating the 'health' of a structure by assessing the level of deterioration and remaining service life of civil infrastructure systems. This book reviews key developments in research, technologies, and applications in this area of civil engineering. It discusses ways of obtaining and analyzing data, sensor technologies, and methods of sensing changes in structural performance characteristics. It also discusses data transmission and the application of both individual technologies and entire systems to bridges and buildings.
AbstractList	Structural health monitoring is an extremely important methodology in evaluating the 'health' of a structure by assessing the level of deterioration and remaining service life of civil infrastructure systems. This book reviews key developments in research, technologies and applications in this area of civil engineering. It discusses ways of obtaining and analysing data, sensor technologies and methods of sensing changes in structural performance characteristics. It also discusses data transmission and the application of both individual technologies and entire systems to bridges and buildings.With its distinguished editors and international team of contributors, Structural health monitoring of civil infrastructure systems is a valuable reference for students in civil and structural engineering programs as well as those studying sensors, data analysis and transmission at universities. It will also be an important source for practicing civil engineers and designers, engineers and researchers developing sensors, network systems and methods of data transmission and analysis, policy makers, inspectors and those responsible for the safety and service life of civil infrastructure. Reviews key developments in research, technologies and applicationsDiscusses systems used to obtain and analyse data and sensor technologiesAssesses methods of sensing changes in structural performance Structural health monitoring is an extremely important methodology in evaluating the 'health' of a structure by assessing the level of deterioration and remaining service life of civil infrastructure systems. This book reviews key developments in research, technologies, and applications in this area of civil engineering. It discusses ways of obtaining and analyzing data, sensor technologies, and methods of sensing changes in structural performance characteristics. It also discusses data transmission and the application of both individual technologies and entire systems to bridges and buildings.
Author	Karbhari Vistasp M Ansari Farhad
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SubjectTerms	Infrastructure Nondestructive Testing & Evaluation Structural Health Monitoring Transportation Engineering
TableOfContents	Title Page Table of Contents 1. Structural Health Monitoring: Applications and Data Analysis 2. Piezoelectric Impedance Transducers for Structural Health Monitoring of Civil Infrastructure Systems 3. Wireless Sensors and Networks for Structural Health Monitoring of Civil Infrastructure Systems 4. Synthetic Aperture Radar and Remote Sensing Technologies for Structural Health Monitoring of Civil Infrastructure Systems 5. Magnetoelastic Stress Sensors for Structural Health Monitoring of Civil Infrastructure Systems 6. Vibration-Based Damage Detection Techniques for Structural Health Monitoring of Civil Infrastructure Systems 7. Operational Modal Analysis for Vibration-Based Structural Health Monitoring of Civil Structures 8. Fiber Optic Sensors for Structural Health Monitoring of Civil Infrastructure Systems 9. Data Management and Signal Processing for Structural Health Monitoring of Civil Infrastructure Systems 10. Statistical Pattern Recognition and Damage Detection in Structural Health Monitoring of Civil Infrastructure Systems 11. Structural Health Monitoring of Bridges: General Issues and Applications 12. Structural Health Monitoring of Cable-Supported Bridges in Hong Kong 13. Structural Health Monitoring of Historical Structures 14. Structural Health Monitoring Research in Europe: Trends and Applications 15. Structural Health Monitoring Research in China: Trends and Applications Index Cover -- Structural health monitoring of civil infrastructure systems -- Copyright -- Contents -- Contributor contact details -- Introduction: structural health monitoring - a means to optimal design in the future -- 1 Structural health monitoring: applications and data analysis -- 1.1 Structural health monitoring (SHM) approach -- 1.2 Components for a complete SHM -- 1.3 Application scenarios for decision making -- 1.4 Emerging Role of structural health monitoring for management -- 1.5 Critical considerations for structural health monitoring interpretations -- 1.6 Data analysis, interpretation and some methods -- 1.7 Conclusions -- 1.8 Acknowledgments -- 1.9 References -- Part I Structural health monitoring technologies -- 2 Piezoelectric impedance transducers for structural health monitoring of civil infrastructure systems -- 2.1 Introduction -- 2.2 Electromechanical impedance modeling -- 2.3 Damage assessment -- 2.4 Sensing region of lead zirconate titanate transducers -- 2.5 Practical issues on field applications -- 2.6 Conclusions -- 2.7 References -- 3 Wireless sensors and networks for structural health monitoring of civil infrastructure systems -- 3.1 Introduction -- 3.2 Challenges in wireless monitoring -- 3.3 Hardware requirements for wireless sensors -- 3.4 Wireless sensing prototypes -- 3.5 Embedded data processing -- 3.6 Wireless monitoring: case studies -- 3.7 Wireless sensors and cyber-infrastructures -- 3.8 Wireless feedback control -- 3.9 Future trends -- 3.10 Sources of further information and advice -- 3.11 References and further reading -- 4 Synthetic aperture radar and remote sensing technologies for structural health monitoring of civil infrastructure systems -- 4.1 Introduction -- 4.2 Optical remote sensing: background -- 4.3 Change/damage detection in urban areas -- 4.4 Radar remote sensing: background 12.10 Operation of wind and structural health monitoring system -- 12.11 Application of wind and structural health monitoring system -- 12.12 Conclusions -- 12.13 Acknowledgements -- 12.14 References -- 13 Structural health monitoring of historical structures -- 13.1 Introduction -- 13.2 Inspection techniques -- 13.3 Dynamic testing of ancient masonry buildings -- 13.4 The Holy Shroud Chapel in Turin (Italy) -- 13.5 Conclusions -- 13.6 Acknowledgments -- 13.7 References and bibliography -- 14 Structural health monitoring research in Europe: trends and applications -- 14.1 Structural health monitoring in Europe -- 14.2 Survey of European structural health monitoring networks and events -- 14.3 Main centres with structural health monitoring activities in European countries -- 14.4 Selected examples of structural health monitoring projects in Europe -- 14.5 Future trends -- 14.6 References -- 15 Structural health monitoring research in China: trends and applications -- 15.1 Fiber optic sensing technology -- 15.2 Wireless sensors and sensor networks -- 15.3 Smart cement-based strain gauge -- 15.4 Applications: a structural health monitoring system for an offshore platform -- 15.5 Applications: the national aquatic center for the olympic games 'water cube' -- 15.6 Applications: the Harbin Songhua river bridge -- 15.7 Conclusions -- 15.8 Sources of further information and advice -- 15.9 Acknowledgements -- 15.10 References -- Index 9 Data management and signal processing for structural health monitoring of civil infrastructure systems -- 9.1 Introduction -- 9.2 Data collection and on-site data management -- 9.3 Issues in data communication -- 9.4 Effective storage of structural health monitoring data -- 9.5 Structural health monitoring measurement processing -- 9.6 Future trends -- 9.7 Sources of further information and advice -- 9.8 References -- 10 Statistical pattern recognition and damage detection in structural health monitoring of civil infrastructure systems -- 10.1 Introduction -- 10.2 Case study one: an acoustic emission experiment -- 10.3 Analysis and classification of the AE data -- 10.4 Case study two: damage location on an aircraft wing -- 10.5 Analysis of the aircraft wing data -- 10.6 Discussion and conclusions -- 10.7 Acknowledgements -- 10.8 References and further reading -- Part II Applications of structural health monitoringin civil infrastructure systems -- 11 Structural health monitoring of bridges: general issues and applications -- 11.1 Introduction: bridges and cars -- 11.2 Integrated structural health monitoring systems -- 11.3 Designing and implementing a structural health monitoring system -- 11.4 Bridge monitoring -- 11.5 Application examples -- 11.6 Conclusions -- 11.7 Future trends -- 11.8 Sources of further information and advice -- 11.9 References -- 12 Structural health monitoring of cable-supported bridges in Hong Kong -- 12.1 Introduction -- 12.2 Scope of structural health monitoring system -- 12.3 Modular architecture of structural health monitoring system -- 12.4 Sensory system -- 12.5 Data acquisition and transmission system -- 12.6 Data processing and control system -- 12.7 Structural health evaluation system -- 12.8 Structural health data management system -- 12.9 Inspection and maintenance system 4.5 Side-looking aperture radar -- 4.6 Synthetic aperture radar -- 4.7 Feasibility of change detection by SAR simulation -- 4.8 Change/damage detection using actual satellite SAR data -- 4.9 Light detection and ranging remote sensing -- 4.10 Acknowledgments -- 4.11 References and further reading -- 5 Magnetoelastic stress sensors for structural health monitoring of civil infrastructure systems -- 5.1 Introduction -- 5.2 Stress and magnetization -- 5.3 Magnetoelastic stress sensors -- 5.4 Effect of temperature on magnetic permeability -- 5.5 Magnetoelastic sensor and measurement unit -- 5.6 Application of magnetoelastic sensor on bridges -- 5.7 Conclusions -- 5.8 References -- 6 Vibration-based damage detection techniques for structural health monitoring of civil infrastructure systems -- 6.1 Introduction -- 6.2 Dynamic testing of structures -- 6.3 Overview of vibration-based damage detection -- 6.4 Application to a fiber reinforced polymer rehabilitated bridge structure -- 6.5 Extension to prediction of service life -- 6.6 Future trends -- 6.7 References -- 7 Operational modal analysis for vibration-based structural health monitoring of civil structures -- 7.1 Introduction -- 7.2 Overview of operational modal analysis -- 7.3 The time domain decomposition technique -- 7.4 The frequency domain natural excitation technique -- 7.5 Application of operational modal analysis techniques to highway bridges -- 7.6 Future trends -- 7.7 References -- 8 Fiber optic sensors for structural health monitoring of civil infrastructure systems -- 8.1 History -- 8.2 Fiber optic sensors -- 8.3 White light interferometric sensors -- 8.4 Strain optic law and gage factors -- 8.5 Multiplexing and distributed sensing issues -- 8.6 Applications -- 8.7 Monitoring of bridge cables -- 8.8 Monitoring of cracks -- 8.9 Conclusions -- 8.10 References
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