Advanced search
Publication Cover
Structure and Infrastructure Engineering
Maintenance, Management, Life-Cycle Design and Performance
Volume 12, 2016 - Issue 1
Submit an article Journal homepage
3,445
Views
170
CrossRef citations to date
0
Altmetric
Articles

Life-cycle of structural systems: recent achievements and future directionsFootnote

Dan M. FrangopolDepartment of Civil and Environmental Engineering, Center for Advanced Technology for Large Structural Systems (ATLSS Center), Lehigh University, 117 ATLSS Drive, Bethlehem, PA18015-4729, USACorrespondence[email protected]
View further author information
&
Mohamed SolimanDepartment of Civil and Environmental Engineering, Center for Advanced Technology for Large Structural Systems (ATLSS Center), Lehigh University, 117 ATLSS Drive, Bethlehem, PA18015-4729, USAView further author information
Pages 1-20 | Received 01 Jul 2014, Accepted 11 Dec 2014, Published online: 15 Jan 2015

References

  • ABAQUS (2009). ABAQUS/standard version 6.9 user's manuals. Pawtucket, RI: Hibbit, Karlsson, and Soreson.
  • Akiyama, M., Frangopol, D.M., Arai, M., & Koshimura, S. (2013). Reliability of bridges under tsunami hazard: Emphasis on the 2011 Great East Japan earthquake. Earthquake Spectra, 29, S295–S314.
  • Akiyama, M., Frangopol, D.M., & Matsuzaki, H. (2011). Life-cycle reliability of RC bridge piers under seismic and airborne chloride hazards. Earthquake Engineering and Structural Dynamics, 40, 1671–1687.
  • Akiyama, M., Frangopol, D.M., & Suzuki, M. (2012). Integration of the effects of airborne chlorides into reliability-based durability design of reinforced concrete structures in a marine environment. Structure and Infrastructure Engineering, 8, 125–134.
  • American Association of State Highway and Transportation Officials (2014). AASHTO LRFD bridge design specifications (7th ed.). Washington, DC: American Association of State Highway and Transportation Officials.
  • American Society of Civil Engineers (2014a). ASCE and sustainability. Retrieved from http://www.asce.org/Sustainability/ASCE-and-Sustainability/ASCE–-Sustainability.
  • American Society of Civil Engineers (2014b). Maximizing the value of investments using life cycle cost analysis (ASCE Life Cycle Cost Analysis Report). Retrieved from http://www.asce.org/Infrastructure/Life-Cycle-Cost-Analysis-Report/.
  • Ang, A.H-S., & De Leon, D. (2005). Modeling and analysis of uncertainties for risk-informed decisions in infrastructures engineering. Structure and Infrastructure Engineering, 1, 19–31.
  • Ang, A.H.-S., & Tang, W.H. (1984). Probability concepts in engineering planning and design: Decision, risk and reliability (Vol. II). New York, NY: Wiley.
  • Ang, A.H-S., & Tang, W.H. (2007). Probability concepts in engineering: Emphasis on applications to civil and environmental engineering (2nd ed.). Hoboken, NJ: John Wiley & Sons.
  • Arora, J. (2011). Introduction to optimum design (3rd ed.). New York, NY: Elsevier Academic Press.
  • Barone, G., & Frangopol, D.M. (2013a). Hazard-based optimum lifetime inspection and repair planning for deteriorating structures. Journal of Structural Engineering, 139, 04013017.
  • Barone, G., & Frangopol, D.M. (2013b). Reliability, risk and lifetime distributions as performance indicators for life-cycle maintenance of deteriorating structures. Reliability Engineering and System Safety, 123, 21–37.
  • Barone, G., & Frangopol, D.M. (2014). Life-cycle maintenance of deteriorating structures by multi-objective optimization involving reliability, risk, availability, hazard and cost. Structural Safety, 48, 40–50.
  • Barone, G., Frangopol, D.M., & Soliman, M. (2014). Optimization of life-cycle maintenance of deteriorating bridges considering expected annual system failure rate and expected cumulative cost. Journal of Structural Engineering, 140, 04013043.
  • Bastidas-Arteaga, E., Bressolette, P.H., Chateauneauf, A., & Sánchez-Silva, M. (2009). Probabilistic lifetime assessment of RC structures under coupled corrosion-fatigue deterioration processes. Structural Safety, 31, 84–96.
  • Bastidas-Arteaga, E., Chateauneauf, A., Sanchez-Silva, M., Bressolette, P.H., & Schoefs, F. (2010). Influence of weather and global warming in chloride ingress into concrete: A stochastic approach. Structural Safety, 32, 238–249.
  • Biondini, F., Bontempi, F., Frangopol, D.M., & Malerba, P.G. (2006). Probabilistic service life assessment and maintenance planning of concrete structures. Journal of Structural Engineering, 132, 810–825.
  • Biondini, F., Camnasio, E., & Palermo, A. (2014). Lifetime seismic performance of concrete bridges exposed to corrosion. Structure and Infrastructure Engineering, 10, 880–900.
  • Biondini, F., & Frangopol, D.M. (2008). Probabilistic limit analysis and lifetime prediction of concrete structures. Structure and Infrastructure Engineering, 4, 399–412.
  • Bjarnadottir, S., Li, Y., & Stewart, M.G. (2011). A probabilistic-based framework for impact and adaptation assessment of climate change on hurricane damage risk and costs. Structural Safety, 33, 173–185.
  • Bocchini, P. (2013). Computational procedure for the assisted multi-phase resilience-oriented disaster management of transportation systems. In G. Deodatis, B.R. Ellingwood, & Frangopol (Eds.), Safety, reliability, risk, and life-cycle performance of structures and infrastructures (pp. 581–588). London: CRC Press, Taylor and Francis Group.
  • Bocchini, P., & Frangopol, D.M. (2011). A probabilistic computational framework for bridge network optimal maintenance scheduling. Reliability Engineering and System Safety, 96, 332–349.
  • Bocchini, P., & Frangopol, D.M. (2012). Optimal resilience- and cost-based postdisaster intervention prioritization for bridges along a highway segment. Journal of Bridge Engineering, 17, 117–129.
  • Bocchini, P., & Frangopol, D.M. (2013). Connectivity-based optimal scheduling for maintenance of bridge networks. Journal of Engineering Mechanics, 139, 170–769.
  • Bocchini, P., Frangopol, D.M., Ummenhofer, T., & Zinke, T. (2014). Resilience and sustainability of the civil infrastructure: Towards a unified approach. Journal of Infrastructure Systems, 20, 0414004.
  • British Standards Institute (2005). Guide to methods for assessing the acceptability of flaws in metallic structures (BS7910). London: British Standards Institute.
  • Brown, N.J.K., Gearhart, J.L., Jones, D.A., Nozick, L.K., Romero, N., & Xu, N. (2013). Multi-objective optimization for bridge retrofit to address earthquake hazards. In Proceedings of the 2013 Winter Simulation Conference (pp. 2475–2486). Catonsville, MD: INFORMS Simulation Society.
  • Bruneau, M., Chang, S.E., Eguchi, R.T., Lee, G.C., O'Rourke, T.D., Reinhorn, A.M., Shinozuka, M., Tierney, K., Wallace, W.A., & von Winterfeldt, D. (2003). A framework to quantitatively assess and enhance the seismic resilience of communities. Earthquake Spectra, 19, 733–752.
  • Chang, L., Peng, F., Ouyang, Y., Elnashai, A.S., & Spencer, B.F.Jr (2012). Bridge seismic retrofit program planning to maximize postearthquake transportation network capacity. Journal of Infrastructure Systems, 18, 75–88.
  • Chang, S.E., McDaniels, T.L., Mikawoz, J., & Peterson, K. (2007). Infrastructure failure interdependencies in extreme events: Power outage consequences in the 1998 ice storm. Natural Hazards, 41, 337–358.
  • Chang, S.E., & Shinozuka, M. (1996). Life-cycle cost analysis with natural hazard risk. Journal of Infrastructure Systems, 23, 118–126.
  • Chang, S.E., & Shinozuka, M. (2004). Measuring improvements in the disaster resilience of communities. Earthquake Spectra, 20, 739–755.
  • Chung, H., Manuel, L., & Frank, K. (2006). Optimal inspection scheduling of steel bridges using nondestructive testing techniques. Journal of Bridge Engineering, 113, 305–319.
  • Churchill, C.J., & Panesar, D.K. (2013). Life-cycle cost analysis of highway noise barriers designed with photocatalytic cement. Structure and Infrastructure Engineering, 9, 983–998.
  • Cimellaro, G.P., Reinhorn, A.M., & Bruneau, M. (2010a). Framework for analytical quantification of disaster resilience. Engineering Structures, 32, 3639–3649.
  • Cimellaro, G.P., Reinhorn, A.M., & Bruneau, M. (2010b). Seismic resilience of a hospital system. Structure and Infrastructure Engineering, 6, 127–144.
  • Corotis, R.B., Ellis, J.H., & Jiang, M. (2005). Modeling of risk-based inspection, maintenance and life-cycle cost with partially observable Markov decision process. Structure and Infrastructure Engineering, 1, 75–84.
  • Çagnan, Z., Davidson, R.A., & Guikema, S.D. (2006). Post-earthquake restoration planning for Los Angeles electric power. Earthquake Spectra, 22, 589–608.
  • Da Silva, S., & Dias Junior, M. (2007). Statistical damage detection in a stationary rotor systems through time series analysis. Latin American Applied Research, 37, 243–246.
  • Decò, A., & Frangopol, D.M. (2011). Risk assessment of highway bridges under multiple hazards. Journal of Risk Research, 14, 1057–1089.
  • Decò, A., & Frangopol, D.M. (2013). Life-cycle risk assessment of spatially distributed aging bridges under seismic and traffic hazards. Earthquake Spectra, 29, 127–153.
  • Dong, Y., Frangopol, D.M., & Sabatino, S. (2015). Optimizing bridge network retrofit planning based on cost-benefit evaluation and multi-attribute utility associated with sustainability. Earthquake Spectra (in press).
  • Dong, Y., Frangopol, D.M., & Saydam, D. (2013). Time-variant sustainability assessment of seismically vulnerable bridges subjected to multiple hazards. Earthquake Engineering and Structural Dynamics, 42, 1451–1467.
  • Dong, Y., Frangopol, D.M., & Saydam, D. (2014a). Sustainability of highway bridge networks under seismic hazard. Journal of Earthquake Engineering, 18, 41–66.
  • Dong, Y., Frangopol, D.M., & Saydam, D. (2014b). Pre-earthquake multi-objective probabilistic retrofit optimization of bridge networks based on sustainability. Journal of Bridge Engineering, 19, 04014004.
  • El Hassan, J., Bressolette, P., Chateauneauf, A., & El Tawil, K. (2010). Reliability-based assessment of the effect of climate conditions on the corrosion of RC structures subjected to chloride ingress. Engineering Structures, 32, 3279–3287.
  • Ellingwood, B.R. (2005). Risk-informed condition assessment of civil infrastructure: State of practice and research issues. Structure and Infrastructure Engineering, 1, 7–18.
  • Ellingwood, B.R. (2006). Mitigating risk from abnormal loads and progressive collapse. Journal of Performance of Constructed Facilities, 20, 315–323.
  • Ellingwood, B.R., & Kinali, K. (2009). Quantifying and communicating uncertainty in seismic risk assessment. Structural Safety, 31, 179–187.
  • Enright, M.P., & Frangopol, D.M. (1999). Maintenance planning for deteriorating concrete bridges. Journal of Structural Engineering, 125, 1407–1414.
  • Estes, A.C., & Frangopol, D.M. (1998). RELSYS: A computer program for structural system reliability analysis. Structural Engineering and Mechanics, 6, 901–919.
  • Estes, A.C., & Frangopol, D.M. (1999). Repair optimization of highway bridges using system reliability approach. Journal of Structural Engineering, 125, 766–775.
  • Estes, A.C., & Frangopol, D.M. (2001). Minimum expected cost-oriented optimal maintenance planning for deteriorating structures: Application to concrete bridge decks. Reliability Engineering and System Safety, 73, 281–291.
  • Faddoul, R., Raphael, W., & Chateauneuf, A. (2011). A generalised partially observable Markov decision process updated by decision trees for maintenance optimisation. Structure and Infrastructure Engineering, 7, 783–796.
  • Farrar, C.R., Duffey, T.A., Doebling, S.W., & Nix, D.A. (1999). A statistical pattern recognition paradigm for vibration-based structural health monitoring. In Proceedings of the 2nd international workshop on structural health monitoring (pp. 764–773). Stanford, CA: Structures And Composites Laboratory, Stanford University.
  • Faturechi, R., & Miller-Hooks, E. (2013). A mathematical framework for quantifying and optimizing protective actions for civil infrastructure systems. Computer-Aided Civil and Infrastructure Engineering. 10.1111/mice.12027.
  • Frangopol, D.M. (2011). Life-cycle performance, management, and optimization of structural systems under uncertainty: Accomplishments and challenges. Structure and Infrastructure Engineering, 7, 389–413.
  • Frangopol, D.M., & Akiyama, M. (2011). Lifetime seismic reliability analysis of corroded reinforced concrete bridge piers, Chapter 23. In M.Papadrakakis, M.Fragiadakis, & N.D.Lagaros (Eds.), Computational methods in earthquake engineering. In E. Onate (Series Ed.), Computational methods in applied sciences, (Vol. 21, pp. 527–537). Dordrecht: Springer Science+Business Media B.V.
  • Frangopol, D.M., & Bocchini, P. (2011). Resilience as optimization criterion for the bridge rehabilitation of a transportation network subject to earthquake. In D.Ames, T.L.Droessler, & M.Hoit (Eds.), Proceedings of the 2011 ASCE structures congress (pp. 2044–2055). Reston, VA: ASCE.
  • Frangopol, D.M., & Bocchini, P. (2012). Bridge network performance, maintenance and optimisation under uncertainty: Accomplishments and challenges. Structure and Infrastructure Engineering, 8, 341–356.
  • Frangopol, D.M., Bocchini, P., Deco, A., Kim, S., Kwon, K., Okasha, N.M., & Saydam, D. (2012). Integrated life-cycle framework for maintenance, monitoring, and reliability of naval ship structures. Naval Engineers Journal, 124, 89–99.
  • Frangopol, D.M., & Estes, A.C. (1997). Lifetime bridge maintenance strategies based on system reliability. Structural Engineering International, 7, 193–198.
  • Frangopol, D.M., & Okasha, N.M. (2009). Multi-criteria optimisation of life-cycle maintenance programs using advanced modelling and computational tools. In Trends in civil and structural computing (pp. 1–26). Stirlingshire: Saxe-Coburg Publications.
  • Frangopol, D.M., Strauss, A., & Kim, S. (2008a). Bridge reliability assessment based on monitoring. Journal of Bridge Engineering, 13, 258–270.
  • Frangopol, D.M., Strauss, A., & Kim, S. (2008b). Use of monitoring extreme data for the performance prediction of structures: General approach. Engineering Structures, 30, 3644–3653.
  • Furuta, H., Frangopol, D.M., & Nakatsu, K. (2011). Life-cycle cost of civil infrastructure with emphasis on balancing structural performance and seismic risk of road network. Structure and Infrastructure Engineering, 7, 65–74.
  • Furuta, H., Kameda, T., Fukuda, Y., & Frangopol, D.M. (2004). Life-cycle cost analysis for infrastructure systems: Life cycle cost vs. safety level vs. service life. Life-Cycle Performance of Deteriorating Structures: Assessment, Design and Management, ASCE, 19–25.
  • Garbatov, Y., & Guedes Soares, C. (2001). Cost and reliability based strategies for fatigue maintenance planning of floating structures. Reliability Engineering and System Safety, 73, 293–301.
  • Ghosh, J., & Padgett, J.E. (2010). Aging considerations in the development of time-dependent seismic fragility curves. Journal of Structural Engineering, 136, 1497–1511.
  • Gul, M., & Catbas, F.N. (2009). Statistical pattern recognition for structural health monitoring using time series modeling: Theory and experimental verifications. Mechanical Systems and Signal Processing, 23, 2192–2204.
  • Gul, M., & Catbas, F.N. (2011). Structural health monitoring and damage assessment using a novel time series analysis methodology with sensor clustering. Journal of Sound and Vibration, 330, 1196–1210.
  • Iman, R.L. (2008). Latin hypercube sampling. In E.L.Melnick & B.S.Everitt (Eds.), Encyclopedia of quantitative risk analysis and assessment (pp. 1–5). Hoboken, NJ: John Wiley & Sons, Ltd.
  • Jacques, C.C., McIntosh, J., Giovinazzi, S., Kirsch, T.D., Wilson, T., & Mitrani-Reiser, J. (2014). Resilience of the Canterbury hospital system to the 2011 Christchurch earthquake. Earthquake Spectra. 10.1193/032013EQS074M.
  • Jayaram, N., & Baker, J.W. (2010). Efficient sampling and data reduction techniques for probabilistic seismic lifeline risk assessment. Earthquake Engineering and Structural Dynamics, 39, 1109–1131.
  • Jiménez, A., Ríos-Insua, S., & Mateos, A. (2003). A decision support system for multiattribute utility evaluation based on imprecise assignments. Decision Support Systems, 36, 65–79.
  • Joint Committee on Structural Safety (2008). Risk assessment in engineering: Principles, system representation and risk criteria. In M.H.Faber (Ed.), Risk assessment in engineering (pp. 5–13). Denmark: Joint Committee on Structural Safety.
  • Karmakar, D., Ray-Chaudhuri, S., & Shinozuka, M. (2014). Finite element model development, validation and probabilistic seismic performance evaluation of Vincent Thomas suspension bridge. Structure and Infrastructure Engineering. 10.1080/15732479.2013.863360.
  • Kendall, A., Keoleian, G., & Helfand, G. (2008). Integrated life-cycle assessment and life-cycle cost analysis model for concrete bridge deck applications. Journal of Infrastructure Systems, 14, 214–222.
  • Kim, S., & Frangopol, D.M. (2011a). Cost-based optimum scheduling of inspection and monitoring for fatigue sensitive structures under uncertainty. Journal of Structural Engineering, 137, 1319–1331.
  • Kim, S., & Frangopol, D.M. (2011b). Inspection and monitoring planning for RC structures based on minimization of expected damage detection delay. Probabilistic Engineering Mechanics, 26, 308–320.
  • Kim, S., & Frangopol, D.M. (2011c). Optimum inspection planning for minimizing fatigue damage detection delay of ship hull structures. International Journal of Fatigue, 33, 448–459.
  • Kim, S., & Frangopol, D.M. (2012). Probabilistic bicriterion optimum inspection/monitoring planning: Application to naval ships and bridges under fatigue. Structure and Infrastructure Engineering, 8, 912–927.
  • Kim, S., Frangopol, D.M., & Soliman, M. (2013). Generalized probabilistic framework for optimum inspection and maintenance planning. Journal of Structural Engineering, 139, 435–447.
  • Kong, J.S., & Frangopol, D.M. (2003a). Life-cycle reliability-based maintenance cost optimization of deteriorating structures with emphasis on bridges. Journal of Structural Engineering, 129, 818–828.
  • Kong, J.S., & Frangopol, D.M. (2003b). Evaluation of expected life-cycle maintenance cost of deteriorating structures. Journal of Structural Engineering, 129, 682–691.
  • Kong, J.S., & Frangopol, D.M. (2004a). Prediction of reliability and cost profiles of deteriorating structures under time- and performance-controlled maintenance. Journal of Structural Engineering, 130, 1865–1874.
  • Kong, J.S., & Frangopol, D.M. (2004b). Cost-reliability interaction in life-cycle cost optimization of deteriorating structures. Journal of Structural Engineering, 130, 1704–1712.
  • Kong, J.S., & Frangopol, D.M. (2005). Probabilistic optimization of aging structures considering maintenance and failure costs. Journal of Structural Engineering, 131, 600–616.
  • Kwon, K., & Frangopol, D.M. (2010). Bridge fatigue reliability assessment using probability density functions of equivalent stress range based on field monitoring data. International Journal of Fatigue, 32, 1221–1232.
  • Kwon, K., & Frangopol, D.M. (2011). Bridge fatigue assessment and management using reliability-based crack growth and probability of detection models. Probabilistic Engineering Mechanics, 26, 471–480.
  • Kwon, K., & Frangopol, D.M. (2012). Fatigue life assessment and lifetime management of aluminum ships using life-cycle optimization. Journal of Ship Research, 56, 91–105.
  • Leemis, L.M. (1995). Reliability, probabilistic models and statistical methods. Upper Saddle River, NJ: Prentice Hall.
  • Li, Y., & Ellingwood, B.R. (2006). Hurricane damage to residential construction in the US: Importance of uncertainty modeling in risk assessment. Engineering Structures, 28, 1009–1018.
  • Liu, M., & Frangopol, D.M. (2005a). Bridge annual maintenance prioritisation under uncertainty by multiobjective combinatorial optimisation. Computer-Aided Civil and Infrastructure Engineering, 20, 343–352.
  • Liu, M., & Frangopol, D.M. (2005b). Balancing connectivity reliability of deteriorating bridge networks and long-term maintenance cost through optimization. Journal of Bridge Engineering, 10, 468–481.
  • Liu, M., & Frangopol, D.M. (2005c). Multiobjective maintenance planning optimisation for deteriorating bridges considering condition, safety, and life-cycle cost. Journal of Structural Engineering, 131, 833–842.
  • Liu, M., & Frangopol, D.M. (2006). Optimising bridge network maintenance management under uncertainty with conflicting criteria: Life-cycle maintenance, failure and user costs. Journal of Structural Engineering, 131, 1835–1845.
  • Liu, M., Frangopol, D.M., & Kwon, K. (2010). Fatigue reliability assessment of retrofitted steel bridges integrating monitoring data. Structural Safety, 32, 77–89.
  • Liu, M., Giovinazzi, S., MacGeorge, R., & Beukman, P. (2013). Wastewater network restoration following the Canterbury, NZ earthquake sequence: Turning post-earthquake recovery into resilience enhancement. International Efforts in Lifeline Earthquake Engineering. 10.1061/9780784413234.021.
  • Lundie, S., Peters, G.M., & Beavis, P.C. (2004). Life cycle assessment for sustainable metropolitan water systems planning. Environmental Science and Technology, 38, 3465–3473.
  • Mackie, K.R., Wong, J., & Stojadinovic, B. (2010). Post-earthquake bridge repair cost and repair time estimation methodology. Earthquake Engineering and Structural Dynamics, 39, 281–301.
  • MathWorks (2014a). MATLAB programming fundamentals. Natick, MA: The MathWorks.
  • MathWorks (2014b). Global optimization toolbox user's guide. Natick, MA: The MathWorks.
  • Mattson, S.G., & Pandit, S.M. (2006). Statistical moments of autoregressive model residuals for damage localisation. Mechanical Systems and Signal Processing, 20, 627–645.
  • Melchers, R.E. (1999). Structural reliability analysis and prediction (2nd ed.). Chichester: John Wiley & Sons Ltd.
  • Metropolis, N., Rosenbluth, A., Rosenbluth, M., Teller, A., & Teller, M. (1953). Equation of state calculations by fast computing machines. The Journal of Chemical Physics, 21, 1087–1092.
  • Moan, T., & Song, R. (2000). Implications of inspection updating on system fatigue reliability of offshore structures. Journal of Offshore Mechanics and Arctic Engineering, 122, 173–180.
  • Modarres, M. (2006). Risk analysis in engineering: Techniques, tools, and trends. London: CRC Press, Taylor and Francis Group.
  • Nair, K.K., Kiremidjian, A.S., & Law, K.H. (2006). Time series-based damage detection and localization algorithm with application to the ASCE benchmark structure. Journal of Sound and Vibration, 291, 349–368.
  • Neal, R.M. (2003). Slice sampling. The Annuals of Statistics, 31, 705–767.
  • Neves, L.C., Frangopol, D.M., & Cruz, P.J. (2006). Probabilistic lifetime-oriented multi-objective optimisation of bridge maintenance: Single maintenance type. Journal of Structural Engineering, 132, 991–1005.
  • Nigro, M., Pakzad, S., & Dorvash, S. (2014). Localized structural damage detection: A change point analysis. Computer-Aided Civil and Infrastructure Engineering. 10.1111/mice.12059.
  • Noh, H., Rajagopal, R., & Kiremidjian, A.S. (2013). Sequential structural damage diagnosis algorithm using a change point detection method. Journal of Sound and Vibration, 332, 6419–6433.
  • Okasha, N.M., & Frangopol, D.M. (2009). Lifetime oriented multi-objective optimisation of structural maintenance considering system reliability, redundancy and life-cycle cost using GA. Structural Safety, 31, 460–474.
  • Okasha, N.M., & Frangopol, D.M. (2010a). Novel approach for multi-criteria optimization of life-cycle preventive and essential maintenance of deteriorating structures. Journal of Structural Engineering, 136, 1009–1022.
  • Okasha, N.M., & Frangopol, D.M. (2010b). Redundancy of structural systems with and without maintenance: An approach based on lifetime functions. Reliability Engineering and System Safety, 95, 520–533.
  • Okasha, N.M., & Frangopol, D.M. (2012). Integration of structural health monitoring in a system performance based life-cycle bridge management framework. Structure and Infrastructure Engineering, 8, 999–1016.
  • Okasha, N.M., Frangopol, D.M., & Decò, A. (2010). Integration of structural health monitoring in life-cycle performance assessment of ship structures under uncertainty. Marine Structures, 23, 303–321.
  • Okasha, N.M., Frangopol, D.M., & Orcesi, A.D. (2012). Automated finite element updating using strain data for the lifetime reliability assessment of bridges. Reliability Engineering and System Safety, 99, 139–150.
  • Okasha, N.M., Frangopol, D.M., Saydam, D., & Salvino, L.W. (2011). Reliability analysis and damage detection in high-speed naval craft based on structural health monitoring data. Structural Health Monitoring, 10, 361–379.
  • Otieno, M.B., Beushausen, H.D., & Alexander, M.G. (2011). Modelling corrosion propagation in reinforced concrete structures — A critical review. Cement and Concrete Composites, 33, 240–245.
  • Ouyang, M., Dueñas-Osorio, L., & Min, X. (2012). A three-stage resilience analysis framework for urban infrastructure systems. Structural Safety, 36, 23–31.
  • Padgett, J.E., Dennemann, K., & Ghosh, J. (2010). Risk-based seismic life-cycle cost-benefit LCC-B analysis for bridge retrofit assessment. Structural Safety, 32, 165–173.
  • Padgett, J.E., & DesRoches, R. (2007). Bridge functionality relationships for improved seismic risk assessment of transportation networks. Earthquake Spectra, 23, 115–130.
  • Padgett, J.E., & Tapia, C. (2013). Sustainability of natural hazard risk mitigation: Life cycle analysis of environmental indicators for bridge infrastructure. Journal of Infrastructure Systems, 19, 395–408.
  • Papakonstantinou, K.G., & Shinozuka, M. (2013). Probabilistic model for steel corrosion in reinforced concrete structures of large dimensions considering crack effects. Engineering Structures, 57, 306–326.
  • Papakonstantinou, K.G., & Shinozuka, M. (2014). Optimum inspection and maintenance policies for corroded structures using partially observable Markov decision processes and stochastic, physically based models. Probabilistic Engineering Mechanics, 37, 93–108.
  • Perrin, F., Sudret, B., & Pendola, M. (2007). Bayesian updating of mechanical models-application in fracture mechanics. In Proceedings of the 18 Ème Congrès Françes De Mèçanique (pp. 27–32). Courbevoie, France: AFM, Maison de la Mécanique.
  • Pindyck, R.S. (2013). Pricing carbon when we don't know the right price. Regulation (Cato Institute)36, 43–46.
  • Rausand, M., & Høyland, A. (2004). System reliability theory: Models, statistical methods, and applications. New York, NY: John Wiley & Sons.
  • Rinaldi, S.M. (2004). Modeling and simulating critical infrastructures and their interdependencies. In Proceedings of the 37th annual Hawaii international conference on system sciences. IEEE. doi:10.1109/HICSS.2004.1265180.
  • Rokneddin, K., Ghosh, J., Dueñas-Osorio, L., & Padgett, J.E. (2013). Bridge retrofit prioritisation for ageing transportation networks subject to seismic hazards. Structure and Infrastructure Engineering, 9, 1050–1066.
  • Saydam, D., Bocchini, P., & Frangopol, D.M. (2013). Time-dependent risk associated with deterioration of highway bridge networks. Engineering Structures, 54, 221–233.
  • Saydam, D., & Frangopol, D.M. (2011). Time-dependent performance indicators of damaged bridge superstructures. Engineering Structures, 33, 2458–2471.
  • Shinozuka, M., Murachi, Y., Dong, X., Zhou, Y., & Orlikowski, M.J. (2003). Effect of seismic retrofit of bridges on transportation networks. Earthquake Engineering and Engineering Vibration, 2, 169–179.
  • Shiraki, N., Shinozuka, M., Moore, J.E., Chang, S.E., Kameda, H., & Tanaka, S. (2007). System risk curves: Probabilistic performance scenarios for highway networks subject to earthquake damage. Journal of Infrastructure Systems, 13, 43–54.
  • Sohn, H., Czarnecki, J.A., & Farrar, C.R. (2000). Structural health monitoring using statistical process control. Journal of Structural Engineering, 126, 1356–1363.
  • Sohn, H., & Farrar, C.R. (2001). Damage diagnosis using time series analysis of vibration signals. Smart Materials and Structures, 10, 446–451.
  • Sohn, H., Farrar, C.R., Hunter, N.F., & Worden, K. (2001). Structural health monitoring using statistical pattern recognition techniques. Journal of Dynamic Systems, Measurement, and Control, 123, 706–711.
  • Soliman, M., & Frangopol, D.M. (2014). Life-cycle management of fatigue sensitive structures integrating inspection information. Journal of Infrastructure Systems, 20, 04014001.
  • Soliman, M., & Frangopol, D.M. (2015). Life-cycle cost evaluation of conventional and corrosion-resistant steel for bridges. Journal of Bridge Engineering, 20, 0614005.
  • Soliman, M., Frangopol, D.M., & Kim, S. (2013). Probabilistic optimum inspection planning of steel bridges with multiple fatigue sensitive details. Engineering Structures, 49, 996–1006.
  • Stein, S., Young, G., Trent, R., & Pearson, D. (1999). Prioritizing scour vulnerable bridges using risk. Journal of Infrastructure Systems, 5, 95–101.
  • Stewart, M.G., Wang, X., & Nguyen, M.N. (2011). Climate change impact and risks of concrete infrastructure deterioration. Engineering Structures, 33, 1326–1337.
  • Stewart, M.G., Wang, X., & Nguyen, M.N. (2012). Climate change adaptation for corrosion control of concrete infrastructure. Structural Safety, 35, 29–39.
  • Stewart, T.J. (1996). Robustness of additive value function methods in MCDM. Journal of Multi-Criteria Decision Analysis, 5, 301–309.
  • Strauss, A., Frangopol, D.M., & Kim, S. (2008). Use of monitoring extreme data for the performance prediction of structures: Bayesian updating. Engineering Structures, 30, 3654–3666.
  • Tartakovsky, A., & Veeravalli, V. (2005). General asymptotic Bayesian theory of quickest change detection. Theory of Probability and Its Applications, 49, 458–497.
  • Turconi, R., Simonsen, C.G., Byriel, I.P., & Astrup, T. (2014). Life cycle assessment of the Danish electricity distribution network. The International Journal of Life Cycle Assessment, 19, 100–108.
  • Venkittaraman, A., & Banerjee, S. (2013). Enhancing resilience of highway bridges through seismic retrofit. Earthquake Engineering and Structural Dynamics. 10.1002/eqe.2392.
  • VisualDOC (2012). VisualDOC user's manual, version 7.1. Colorado Springs, CO: Vanderplaats Research and Development.
  • Zheng, H., & Mita, A. (2007). Two-stage damage diagnosis based on the distance between ARMA models and pre-whitening filters. Smart Materials and Structures, 16, 1829–1836.
  • Zheng, R., & Ellingwood, B.R. (1998). Role of non-destructive evaluation in time-dependent reliability analysis. Structural Safety, 20, 325–339.
  • Zhou, Y., Banerjee, S., & Shinozuka, M. (2010). Socio-economic effect of seismic retrofit of bridges for highway transportation networks: A pilot study. Structure and Infrastructure Engineering, 6, 145–157.
  • Zhu, B., & Frangopol, D.M. (2013a). Risk-based approach for optimum maintenance of bridges under traffic and earthquake loads. Journal of Structural Engineering, 139, 422–434.
  • Zhu, B., & Frangopol, D.M. (2013b). Incorporation of structural health monitoring data on load effects in the reliability and redundancy assessment of ship cross-sections using Bayesian updating. Structural Health Monitoring, 12, 377–392.

Reprints and Corporate Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

To request a reprint or corporate permissions for this article, please click on the relevant link below:

Order Reprints Request Corporate Permissions

Academic Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

Obtain permissions instantly via Rightslink by clicking on the button below:

Request Academic Permissions

If you are unable to obtain permissions via Rightslink, please complete and submit this Permissions form. For more information, please visit our Permissions help page.

Related research

People also read lists articles that other readers of this article have read.

Recommended articles lists articles that we recommend and is powered by our AI driven recommendation engine.

Cited by lists all citing articles based on Crossref citations.
Articles with the Crossref icon will open in a new tab.