Citation: | Jeffrey M. Keisler, Emily M. Wells, Igor Linkov. A Multicriteria Decision Analytic Approach to Systems Resilience[J]. International Journal of Disaster Risk Science, 2024, 15(5): 657-672. doi: 10.1007/s13753-024-00587-1 |
[1] |
American Society of Civil Engineers. 2021. Hazard-resilient infrastructure: Analysis and design. Reston, VA: American Society of Civil Engineers.
|
[2] |
Aruldoss, M. 2013. A survey on multi criteria decision making methods and its applications. American Journal of Information Systems 1(1): 31-43.
|
[3] |
Ayyub, B.M. 2014. Systems resilience for multihazard environments: Definition, metrics, and valuation for decision making. Risk Analysis 34(2): 340-355.
|
[4] |
Ayyub, B.M. 2015. Practical resilience metrics for planning, design, and decision making. ASCE-ASME Journal of Risk and Uncertainty in Engineering Systems, Part A: Civil Engineering 1(3): Article 04015008.
|
[5] |
Bonstrom, H., and R.B. Corotis. 2014. First-order reliability approach to quantify and improve building portfolio resilience. Journal of Structural Engineering 142(8): Article C4014001.
|
[6] |
Bostick, T.P., E.B. Connelly, J.H. Lambert, and I. Linkov. 2018. Resilience science, policy and investment for civil infrastructure. Reliability Engineering & System Safety 175: 19-23.
|
[7] |
Bruneau, M., and A.M. Reinhorn. 2018. Structural engineering dilemmas, resilient EPCOT, and other perspectives on the road to engineering resilience. In Routledge handbook of sustainable and resilient infrastructure, ed. P. Gardoni, 70-93. London: Routledge.
|
[8] |
Burnett, J.T., and C.M. Edgeley. 2023. Factors influencing flood risk mitigation after wildfire: Insights for individual and collective action after the 2010 Schultz Fire. International Journal of Disaster Risk Reduction 94: Article 103791.
|
[9] |
Cegan, J.C., A.M. Filion, J.M. Keisler, and I. Linkov. 2017. Trends and applications of multi-criteria decision analysis in environmental sciences: Literature review. Environment Systems and Decisions 37(2): 123-133.
|
[10] |
Cinelli, M., M. Spada, W. Kim, Y. Zhang, and P. Burgherr. 2021. MCDA Index Tool: An interactive software for developing indices and rankings. Environment Systems and Decisions 41(1): 82-109.
|
[11] |
Cutter, S.L., J.A. Ahearn, B. Amadei, P. Crawford, E.A. Eide, G.E. Galloway, M.F. Goodchild, and H. Kunreuther et al. 2013. Disaster resilience: A national imperative. Environment 55(2): 25-29.
|
[12] |
Davis, C.A., B. Ayyub, S. McNeil, K. Kobayashi, H. Tatano, M. Onishi, Y. Takahashi, and R. Honda et al. 2022. Overview of a framework to engineer infrastructure resilience through assessment, management, and governance. In Lifelines 2022: Advancing lifeline engineering for community resilience, ed. C.A. Davis, K. Yu, and E. Taciroglu, 901-1013. Reston, VA: American Society of Civil Engineers.
|
[13] |
Debano, L.F. 2000. The role of fire and soil heating on water repellency in wildland environments: A review. Journal of Hydrology 231-232: 195-206.
|
[14] |
Doerr, S.H., and A.D. Thomas. 2000. The role of soil moisture in controlling water repellency: New evidence from forest soils in Portugal. Journal of Hydrology 231-232: 134-147.
|
[15] |
Dormady, N., A. Rose, H. Rosoff, and A. Roa-Henriquez. 2019. Estimating the cost-effectiveness of resilience to disasters: Survey instrument design & refinement of primary data. In Handbook on resilience of socio-technical systems, ed. M. Ruth, and S.G. Reisemann, 227-246. Cheltenham: Edward Elgar.
|
[16] |
Dormady, N., A. Rose, C.B. Morin, and A. Roa-Henriquez. 2022. The cost-effectiveness of economic resilience. International Journal of Production Economics 244: Article 108371.
|
[17] |
Federal Emergency Management Agency. 2020. FEMA fact sheet flood after fire flood risks increase after fires. Washington, DC: Federal Emergency Management Agency.
|
[18] |
Ferris, T.L.J. 2019. A resilience measure to guide system design and management. IEEE Systems Journal 13(4): 3708-3715.
|
[19] |
Fox-Lent, C., M.E. Bates, and I. Linkov. 2015. A matrix approach to community resilience assessment: An illustrative case at Rockaway Peninsula. Environment Systems and Decisions 35(2): 209-218.
|
[20] |
Ganin, A.A., E. Massaro, A. Gutfraind, N. Steen, J.M. Keisler, A. Kott, R. Mangoubi, and I. Linkov. 2016. Operational resilience: Concepts, design and analysis. Scientific Reports 6: Article 19540.
|
[21] |
Girona-García, A., D.C.S. Vieira, J. Silva, C. Fernández, P.R. Robichaud, and J.J. Keizer. 2021. Effectiveness of post-fire soil erosion mitigation treatments: A systematic review and meta-analysis. Earth-Science Reviews 217: Article 103611.
|
[22] |
Griffiths, P.G., C.S. Magirl, R.H. Webb, E. Pytlak, P.A. Troch, and S.W. Lyon. 2009. Spatial distribution and frequency of precipitation during an extreme event: July 2006 mesoscale convective complexes and floods in southeastern Arizona. Water Resources Research 45(7). https://doi.org/10.1029/2008WR007380.
|
[23] |
Henry, D., and J.E. Ramirez-Marquez. 2012. Generic metrics and quantitative approaches for system resilience as a function of time. Reliability Engineering & System Safety 99: 114-122.
|
[24] |
Huang, I.B., J. Keisler, and I. Linkov. 2011. Multi-criteria decision analysis in environmental sciences: Ten years of applications and trends. Science of the Total Environment 409(19): 3578-3594.
|
[25] |
Izuakor, C., and R. White. 2016. Critical infrastructure asset identification: Policy, methodology and gap analysis. IFIP Advances in Information and Communication Technology 485: 27-41.
|
[26] |
Kabir, G., R. Sadiq, and S. Tesfamariam. 2014. A review of multi-criteria decision-making methods for infrastructure management. Structure and Infrastructure Engineering 10(9): 1176-1210.
|
[27] |
Kean, J.W., D.M. Staley, J.T. Lancaster, F.K. Rengers, B.J. Swanson, J.A. Coe, J.L. Hernandez, and A.J. Sigman et al. 2019. Inundation, flow dynamics, and damage in the 9 January 2018 Montecito debris-flow event, California, USA: Opportunities and challenges for post-wildfire risk assessment. Geosphere 15(4): 1140-1163.
|
[28] |
Keeney, R.L. 2007. Developing objectives and attributes. In Advances in decision analysis, ed. W. Edwards, R.F. Miles, and D. Von Winterfeldt, 104-128. Cambridge, UK: Cambridge University Press.
|
[29] |
Kurth, M.H., S. Larkin, J.M. Keisler, and I. Linkov. 2017. Trends and applications of multi-criteria decision analysis: Use in government agencies. Environment Systems and Decisions 37(2): 134-143.
|
[30] |
Linkov, I., and E. Moberg. 2014. Multi-criteria decision analysis: Environmental applications and case studies. Boca Raton, FL: CRC Press.
|
[31] |
Linkov, I., and B.D. Trump. 2019a. Resilience quantification and assessment. In The science and practice of resilience: Risk, systems and decisions, ed. I. Linkov, J. Keisler, J.H. Lambert, and J.R. Figueira, 81-101. Cham: Springer.
|
[32] |
Linkov, I., and B.D. Trump. 2019b. The science and practice of resilience. Cham: Springer.
|
[33] |
Linkov, I., F.K. Satterstrom, G. Kiker, C. Batchelor, T. Bridges, and E. Ferguson. 2006. From comparative risk assessment to multi-criteria decision analysis and adaptive management: Recent developments and applications. Environment International 32(8): 1072-1093.
|
[34] |
Linkov, I., D.A. Eisenberg, K. Plourde, T.P. Seager, J. Allen, and A. Kott. 2013. Resilience metrics for cyber systems. Environment Systems and Decisions 33(4): 471-476.
|
[35] |
Linkov, I., B.D. Trump, J. Trump, G. Pescaroli, W. Hynes, A. Mavrodieva, and A. Panda. 2022. Resilience stress testing for critical infrastructure. International Journal of Disaster Risk Reduction 82: Article 103323.
|
[36] |
Mabrouk, M., and H. Han. 2023. Urban resilience assessment: A multicriteria approach for identifying urban flood-exposed risky districts using multiple-criteria decision-making tools (MCDM). International Journal of Disaster Risk Reduction 91: Article 103684.
|
[37] |
Malvar, M.C., F.C. Silva, S.A. Prats, D.C.S. Vieira, C.O.A. Coelho, and J.J. Keizer. 2017. Short-term effects of post-fire salvage logging on runoff and soil erosion. Forest Ecology and Management 400: 555-567.
|
[38] |
Marsh, K., E. Zaiser, P. Orfanos, S. Salverda, T. Wilcox, S. Sun, and S. Dixit. 2017. Evaluation of COPD treatments: A multicriteria decision analysis of aclidinium and tiotropium in the United States. Value in Health 20(1): 132-140.
|
[39] |
Martins, M.A.S., F.G.A. Verheijen, M.C. Malvar, D. Serpa, O. González-Pelayo, and J.J. Keizer. 2020. Do wildfire and slope aspect affect soil water repellency in eucalypt plantations?—A two-year high resolution temporal dataset. CATENA 189: Article 104471.
|
[40] |
New Mexico State Forestry. 2015. Post‐fire treatments: A primer for New Mexico communities. https://afterwildfirenm.org/post-fire-treatments/post-fire-treatments-pdf/copy_of_post-fire-treatments-pdf. Accessed 12 Oct 2024.
|
[41] |
Patel, D.A., V.H. Lad, K.A. Chauhan, and K.A. Patel. 2020. Development of bridge resilience index using multicriteria decision-making techniques. Journal of Bridge Engineering 25(10): Article 04020090.
|
[42] |
Pawar, B., M. Huffman, F. Khan, and Q. Wang. 2022. Resilience assessment framework for fast response process systems. Process Safety and Environmental Protection 163: 82-93.
|
[43] |
Poulin, C., and M.B. Kane. 2021. Infrastructure resilience curves: Performance measures and summary metrics. Reliability Engineering & System Safety 216: Article 107926.
|
[44] |
Prasetya, A.R.A., T.A. Rachmawati, and F. Usman. 2023. A multicriteria approach to assessing landslide community resilience. Case study: Bumiaji sub-district. IOP Conference Series: Earth and Environmental Science 1186(1): Article 012003.
|
[45] |
Reutlinger, A., D. Hangleiter, and S. Hartmann. 2018. Understanding (with) toy models. The British Journal for the Philosophy of Science 69(4): 1069-1099.
|
[46] |
Rinaldi, S.M., J.P. Peerenboom, and T.K. Kelly. 2001. Identifying, understanding, and analyzing critical infrastructure interdependencies. IEEE Control Systems Magazine 21(6): 11-25.
|
[47] |
Robichaud, P.R. 2000. Fire effects on infiltration rates after prescribed fire in northern Rocky Mountain forests, USA. Journal of Hydrology 231-232: 220-229.
|
[48] |
Rocco, C.M., E. Hernández-Perdomo, and K. Barker. 2015. Multicriteria decision analysis approach for stochastic ranking with application to network resilience. ASCE-ASME Journal of Risk and Uncertainty in Engineering Systems, Part A: Civil Engineering 2(1): Article 04015018.
|
[49] |
Roege, P.E., Z.A. Collier, J. Mancillas, J.A. McDonagh, and I. Linkov. 2014. Metrics for energy resilience. Energy Policy 72: 249-256.
|
[50] |
Rose, A. 2017. Benefit-cost analysis of economic resilience actions. In Oxford research encyclopedia of natural hazard science, ed. S. Cutter. New York: Oxford University Press. https://doi.org/10.1093/acrefore/9780199389407.013.69. Accessed 12 Oct 2024.
|
[51] |
Roszkowska, E., and T. Wachowicz. 2016. Analyzing the applicability of selected MCDA methods for determining the reliable scoring systems. https://www.researchgate.net/publication/305209304_Analyzing_the_Applicability_of_Selected_MCDA_Methods_for_Determining_the_Reliable_Scoring_Systems. Accessed 12 Oct 2024.
|
[52] |
Sharma, N., A. Tabandeh, and P. Gardoni. 2018. Resilience analysis: A mathematical formulation to model resilience of engineering systems. Sustainable and Resilient Infrastructure 3(2): 49-67.
|
[53] |
Staley, D.M., J.W. Kean, and F.K. Rengers. 2020. The recurrence interval of post-fire debris-flow generating rainfall in the southwestern United States. Geomorphology 370: Article 107392.
|
[54] |
Steele, K., Y. Carmel, J. Cross, and C. Wilcox. 2009. Uses and misuses of multicriteria decision analysis (MCDA) in environmental decision making. Risk Analysis 29(1): 26-33.
|
[55] |
The White House. 2024. National security memorandum on critical infrastructure security and resilience NSM-22. https://www.whitehouse.gov/briefing-room/presidential-actions/2024/04/30/national-security-memorandum-on-critical-infrastructure-security-and-resilience/. Accessed 12 Oct 2024.
|
[56] |
Wang, C., B.M. Ayyub, and A. Ahmed. 2022. Time-dependent reliability and resilience of aging structures exposed to multiple hazards in a changing environment. Resilient Cities and Structures 1(3): 40-51.
|
[57] |
Yang, M., H. Sun, and S. Geng. 2023. On the quantitative resilience assessment of complex engineered systems. Process Safety and Environmental Protection 174: 941-950.
|
[58] |
Yilmaz, O.S., D.E. Akyuz, M. Aksel, M. Dikici, M.A. Akgul, O. Yagci, F.B. Sanli, and H. Aksoy. 2023. Evaluation of pre- and post-fire flood risk by analytical hierarchy process method: A case study for the 2021 wildfires in Bodrum, Turkey. Landscape and Ecological Engineering 19(2): 271-288.
|
[59] |
Zarei, E., B. Ramavandi, A.H. Darabi, and M. Omidvar. 2021. A framework for resilience assessment in process systems using a fuzzy hybrid MCDM model. Journal of Loss Prevention in the Process Industries 69: Article 104375.
|
[60] |
Zhang, Z., P.R. Srivastava, P. Eachempati, and Y. Yu. 2023. An intelligent framework for analyzing supply chain resilience of firms in China: A hybrid multicriteria approach. International Journal of Logistics Management 34(2): 443-472.
|