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Structures and Infrastructure Systems: Life-Cycle Performance, Management, and Optimization
Our knowledge to model, design, analyse, maintain, manage and predict the life-cycle performance of infrastructure systems is continually growing. However, the complexity of these systems continues to increase and an integrated approach is necessary to understand the effect of technological, environmental, economic, social, and political interactions on the life-cycle performance of engineering infrastructure. In order to accomplish this, methods have to be developed to systematically analyse structure and infrastructure systems, and models have to be formulated for evaluating and comparing the risks and benefits associated with various alternatives. Civil engineers must maximize the life-cycle benefits of these systems to serve the needs of our society by selecting the best balance of the safety, economy, resilience and sustainability requirements despite imperfect information and knowledge. Within the context of this book, the necessary concepts are introduced and illustrated with applications to civil and marine structures. This book is intended for an audience of researchers and practitioners world‐wide with a background in civil and marine engineering, as well as people working in infrastructure maintenance, management, cost and optimization analysis. The chapters originally published as articles in Structure and Infrastructure Engineering.

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Structures and Infrastructure Systems: Life-Cycle Performance, Management, and Optimization
Our knowledge to model, design, analyse, maintain, manage and predict the life-cycle performance of infrastructure systems is continually growing. However, the complexity of these systems continues to increase and an integrated approach is necessary to understand the effect of technological, environmental, economic, social, and political interactions on the life-cycle performance of engineering infrastructure. In order to accomplish this, methods have to be developed to systematically analyse structure and infrastructure systems, and models have to be formulated for evaluating and comparing the risks and benefits associated with various alternatives. Civil engineers must maximize the life-cycle benefits of these systems to serve the needs of our society by selecting the best balance of the safety, economy, resilience and sustainability requirements despite imperfect information and knowledge. Within the context of this book, the necessary concepts are introduced and illustrated with applications to civil and marine structures. This book is intended for an audience of researchers and practitioners world‐wide with a background in civil and marine engineering, as well as people working in infrastructure maintenance, management, cost and optimization analysis. The chapters originally published as articles in Structure and Infrastructure Engineering.

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Structures and Infrastructure Systems: Life-Cycle Performance, Management, and Optimization

Structures and Infrastructure Systems: Life-Cycle Performance, Management, and Optimization

Structures and Infrastructure Systems: Life-Cycle Performance, Management, and Optimization

Structures and Infrastructure Systems: Life-Cycle Performance, Management, and Optimization

Overview

Our knowledge to model, design, analyse, maintain, manage and predict the life-cycle performance of infrastructure systems is continually growing. However, the complexity of these systems continues to increase and an integrated approach is necessary to understand the effect of technological, environmental, economic, social, and political interactions on the life-cycle performance of engineering infrastructure. In order to accomplish this, methods have to be developed to systematically analyse structure and infrastructure systems, and models have to be formulated for evaluating and comparing the risks and benefits associated with various alternatives. Civil engineers must maximize the life-cycle benefits of these systems to serve the needs of our society by selecting the best balance of the safety, economy, resilience and sustainability requirements despite imperfect information and knowledge. Within the context of this book, the necessary concepts are introduced and illustrated with applications to civil and marine structures. This book is intended for an audience of researchers and practitioners world‐wide with a background in civil and marine engineering, as well as people working in infrastructure maintenance, management, cost and optimization analysis. The chapters originally published as articles in Structure and Infrastructure Engineering.

Product Details

ISBN-13: 9780367571658
Publisher: CRC Press
Publication date: 06/30/2020
Pages: 406
Product dimensions: 8.62(w) x 10.88(h) x (d)

About the Author

Professor Dan M. Frangopol is the inaugural holder of the Fazlur R. Khan Endowed Chair of Structural Engineering and Architecture at Lehigh University. He has authored/co-authored over 350 articles in archival journals including 9 prize winning papers. He is the Founding Editor of Structure and Infrastructure Engineering and of the Book Series Structures and Infrastructures. He is a foreign member of the Academia Europaea and of the Royal Academy of Belgium, an Honorary Member of the Romanian Academy, and a Distinguished Member of ASCE.

Table of Contents

Preface

State‐of‐the‐art

1. Life‐cycle performance, management, and optimization of structural systems under uncertainty: Accomplishments and challenges
Frangopol, D.M.

2. Bridge network performance, maintenance, and optimization under uncertainty: Accomplishments and challenges
Frangopol, D.M., and Bocchini, P.

3. Life‐cycle of structural systems: recent achievements and future directions,
Frangopol, D.M., and Soliman, M.

4. Bridge life‐cycle performance and cost: Analysis, prediction, optimization, and decision‐making
Frangopol, D.M., Dong, Y., and Sabatino, S.

General Methodology

5. Optimal bridge maintenance planning using improved multi‐objective genetic algorithm
Furuta, H., Kameda.T., Nakahara, K., Takahashi, Y., and Frangopol, D. M.

6. Maintenance and management of civil infrastructure based on condition, safety, optimization, and life‐cycle cost
Frangopol, D.M., and Liu, M.

7. Life‐cycle utility‐informed maintenance planning based on lifetime functions: Optimum balancing of cost, failure consequences, and performance benefit
Sabatino, S., Frangopol, D.M., and Dong, Y.

8. Efficient multi‐objective optimization of probabilistic service life management
Kim, S., and Frangopol, D.M.

Life‐cycle Performance under Corrosion and Fatigue

9. Probabilistic limit analysis and lifetime prediction of concrete structures
Biondini, F., and Frangopol, D.M.

10. Integration of the effects of airborne chlorides into reliability‐based durability design of reinforced concrete structures in a marine environment
Akiyama, M., Frangopol, D.M., and Suzuki, M.

11. Fatigue system reliability analysis of riveted railway bridge connections
Imam, B. M., Chryssanthopoulos, M.K., and Frangopol, D.M

12. Fatigue performance assessment and service life prediction of high‐speed ship structures based on probabilistic lifetime sea loads
Kwon, K., Frangopol, D.M., and Kim, S.

13. Experimental investigation of the spatial variability of the steel weight loss and corrosion cracking of reinforced concrete members: novel X‐ray and digital image processing techniques
Lim, S., Akiyama, M., Frangopol, D.M., and Jiang, H.

14. Reliability‐based durability design and service life assessment of RC deck slab of a jetty structure
Akiyama, M., Frangopol, D.M., and Takenaka, S.

Life‐cycle Performance under Earthquakes

15. Life‐cycle cost of civil infrastructure with emphasis on balancing structural performance and seismic risk of road network
Furuta, H., Frangopol, D.M., and Nakatsu, K.

16. Long‐term seismic performance of RC structures in an aggressive environment: Emphasis on bridge piers
Akiyama, M., and Frangopol, D.M.

17. Performance analysis of Tohoku‐Shinkasen viaducts affected by the 2011 Great East Japan earthquake
Akiyama, M., Frangopol, D.M., and Mizuno, K.

18. Probabilistic assessment of an interdependent healthcare–bridge network system under seismic hazard
Dong, Y., and Frangopol, D.M.

Inspection and Monitoring

19. Application of the statistics of extremes to the reliability assessment and performance prediction of monitored highway bridges
Messervey, T.B., Frangopol, D.M., and Casciati, S.

20. Probabilistic bi‐objective optimum inspection /monitoring planning: applications to naval ships and bridges under fatigue
Kim, S., and Frangopol, D.M.

21. Integration of structural health monitoring in a system performance based life‐cycle bridge management framework
Okasha, N.M., and Frangopol, D.M.

22. Critical issues, condition assessment and monitoring of heavy movable structures: Emphasis on movable bridges
Catbas, F.N., Gul, M., Gokce, H. B., Zaurin, R., Frangopol, D.M., and Grimmelsman, K.

Redundancy as Life‐Cycle Performance Indicator

23. Time‐variant redundancy of structural systems
Okasha, N.M., and Frangopol, D.M.

24. Redundancy and robustness of highway bridge superstructures and substructures
Ghosn, M., Moses, F., and Frangopol, D.M.

25. Effects of post‐failure material behavior on redundancy factors for design of structural components in nondeterministic systems
Zhu, B., and Frangopol, D.M.

26. Time‐variant redundancy and failure times of deteriorating concrete structures considering multiple limit states
Biondini, F., and Frangopol, D.M.

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