[[1] Huang Lang, Wu Chao, Yang Mian, Wang Bing. Application of Resilience Theory in the Field of Safety Science[J]. China Safety Science, 2017, 27(3): 1-6.]Search in Google Scholar
[[2] Zheng Yuxuan. Research on dynamic fragmentation characteristics of ductile materials[D]. Hefei: University of Science and Technology of China, 2013.]Search in Google Scholar
[[3] Zhao Wei. Research on reliable evaluation of fracture toughness of structural ceramics [D]. Guangzhou: South China University of Technology, 2015.]Search in Google Scholar
[[4] Todini E. Looped water distribution design using a resilience index based heuristic approach[J]. Urban Water, 2000, 2(2):115-122.]Search in Google Scholar
[[5] Rose A, Oladosu G, Liao S Y. Business interruption impacts of a terrorist attack on the electric power system of Los Angeles: Customer resilience to a total blackout[J]. Risk Anal, 2007, 27(3):513-531.]Search in Google Scholar
[[6] Bruneau M, Reinhorn A. Overview of the resilience concept[C]//Proceeding of 8th National Seismic Conference. San Francisco, 2006:2040.]Search in Google Scholar
[[7] UN/ISDR. Terminology on disaster risk reduction[EB/OL]. (2009-04-13) [2018-01-22]. http://www.unisdr.org/we/inform/terminology.]Search in Google Scholar
[[8] Syed A, Jayant K R. Earthquake hazards and community resilience in Baluchistan[J]. Natural Hazards, 2012, 63(2):909-937.]Search in Google Scholar
[[9] Crowley K, Elliott J R. Earthquake disasters and resilience in the global north: Lesson from New Zealand and Japan[J]. The Geographical Journal, 2012, 178(3):208-215.]Search in Google Scholar
[[10] Elizabeth J, Amy J W. Measuring community resilience and recovery: A content analysis of indicators[C]//Proceeding of Construction Research Congress, West Lafayette, 2012, 2190-2199.]Search in Google Scholar
[[11] Fujita Y. Learning from the fukushima nuclear power plant accident-A resilience point of view[C]//Proceeding of Network of Ergonomics Societies Conference (SEANES), 2012 Southeast Asian, Langkawi, Kedah, 2012:1-5.]Search in Google Scholar
[[12] Penney A, Martin B, Camila W. The influence of urban Mprphology on the resilience of cities following an earthquake[J]. Journal of Urban Design, 2013, 18(2):242-262.]Search in Google Scholar
[[13] Li Qian, Guo Endong, Yu Tianyang, et al. Evaluation of post-quake resilience of water supply pipelines[J]. Revista de la Facultad de Ingeniería, 2017, 32(10):283-295.]Search in Google Scholar
[[14] Albert R, Jeong H, Barabasi A L. Error and attack tolerance of complex networks[J]. Nature, 2000, 406(6794):378-382.]Search in Google Scholar
[[15] Callaway D S, Newman M E J, Strogatz S H, et al. Network robustness and fragility: Percolation on random graphs[J]. Physical Review Letters, 2000, 85(25):5468.]Search in Google Scholar
[[16] Cohen R, Erez K, Ben-Avraham D, et al. Resilience of the internet to random breakdowns[J]. Physical Review Letters, 2000, 85(21):4626.]Search in Google Scholar
[[17] Paul G, Tanizawa T, Havlin S, et al. Optimization of robustness of complex networks[J]. The European Physical Journal B-Condensed Matter and Complex Systems, 2004, 38(2):187-191.]Search in Google Scholar
[[18] Strogatz S H, Exploring complex networks[J]. Nature, 2001, 410(6825):268-276.]Search in Google Scholar
[[19] Newman M E J. The structure and function of complex networks[J]. SIAM Review, 2003, 45(2):167-256.]Search in Google Scholar
[[20] Boccaletti S, Latora V, Moreno Y, et al. Complex networks:Structure and dynamics[J]. Physics Report, 2006, 424(4):175-308.]Search in Google Scholar
[[21] Jeon S S, O’Rourke T D. Northridge earthquake effects on pipelines and residential buildings[J]. Bull Seismol.Soc.Am., 2005, 95:294-318.]Search in Google Scholar
[[22] Wang Y, Au S K, Fu Q. Seismic risk assessment and mitigation of water supply systems[J]. Earthquake Spectra, 2010, 26(1):257-274.]Search in Google Scholar
[[23] Shi P. Seismic response modeling of water supply system[D]. Cornell University, Ithaca, NY, 2006.]Search in Google Scholar
[[24] Tabucchi T, Davidson R, Brink S. Simulation of post-earthquake water supply system restoration[J]. Civil Engineering and Environmental Systems, 2010, 27(4):263-279.]Search in Google Scholar
[[25] Halfaya F Z, Bensaibi M, Davenne L. Vulnerability assessment of water supply network[J]. Energy Procedia, 2012, 18:772-783.]Search in Google Scholar
[[26] Toprak S, Taskin F. Estimation of earthquake damage to buried pipelines caused by ground shaking[J]. Natural Hazards, 2007, 40(1):1-24.]Search in Google Scholar
[[27] Adachi T, Ellingwood B R. Serviceability of earthquake-damaged water systems: Effects of electrical power availability and power backup systems on system vulnerability[J]. Reliability Engineering and System Safety, 2008, 93:73-88.]Search in Google Scholar
[[28] Mahmood H, Samira J. Assessment of the nonlinear behavior of connections in water distribution networks for their seismic evaluation[J]. Procedia Engineering, 2011, 14:2878-2883.]Search in Google Scholar
[[29] Guo E D, Yang D, Lil Z, et al. Seismic vulnerability analysis of water pipeline in Wenchuan earthquake[J]. Applied Mechanics and Materials, 2011, 109:290-295.]Search in Google Scholar
[[30] National Standards of the People’s Republic of China. China Earthquake Parameter Zoning Map (GB18306-2015) [S]. Beijing: China Standard Press, 2015.]Search in Google Scholar
[[31] National Standard of the People’s Republic of China. Code for Seismic Design of Outdoor Water Supply and Drainage and Gas Heating Engineering (GB50032-2003) [S]. Beijing: China Building Industry Press, 2003.]Search in Google Scholar
[[32] Wu Y, Xu Y, Wang W. A software tool for reliability, analysis, and security assessment of water distribution systems[C]//Proceedings of ICPTT, Wuhan, 2012, 48-55.]Search in Google Scholar
[[33] Mitrani R J, Mahoney M, Holmes W T, et al. A functional loss assessment of a hospital system in the Bio-Bio province[J]. Earthquake Spectra, 2012, 28(S1):473-502.]Search in Google Scholar
[[34] Davis CA. Water system service categories, post-earthquake interaction, and restoration strategies[J]. Earthq Spectra, 2014, 30(4):1487-1509.]Search in Google Scholar
[[35] Ballantyne DB, Berg E, Kennedy J, Reneau R, Wu D. Earthquake loss estimation modeling of the Seattle water system[J]. Technical report. Kennedy/Jenks/Chilton, Federal Way, 1990:139.]Search in Google Scholar
[[36] Taylor CE. Seismic loss estimation for a hypothetical water system[J]. Monograph (Technical Council on Lifeline Earthquake Engineering, ASCE, Reston). 1991(2):88.]Search in Google Scholar
[[37] Shinozuka M, H H, M M. Impact on water supply of a seismically damaged water delivery system[C].//Lifeline Earthquake Engineering in the Central and Eastern US, Technical Council on Lifeline Earthquake Engineering Monograph No5 Ballantyne, D B, ed, ASCE, Reston, VA, 1992:43-57.]Search in Google Scholar
[[38] Markov I, Grigoriu M, O’Rourke T. An evaluation of seismic serviceability water supply networks with application to the San Francisco auxiliary water supply system[C].//Technical report NCEER-94-0001,Nation Center for Earthquake Engineering Research(NCEER), 1994.]Search in Google Scholar
[[39] Hwang HHM, Lin H, Shinozuka M. Seismic performance assessment of water distribution systems[J]. J Infrastruct Syst ASCE, 1998,4(3):118-125.]Search in Google Scholar
[[40] LI X J,SHEN F M.Study on anti-seismic reliability of urban water supply system[J]. Applied Mechanics and Materials, 2012,238:868-871.]Search in Google Scholar
[[41] Zhuang Baoyu, Gao Bin. Risk Assessment of Regional Water Supply System Based on Vulnerability Analysis-Take Tianjin as an Example [C]//Diversity and Inclusiveness-2012, Proceedings of China Urban Planning Annual Conference (08. Urban Safety and Prevention Disaster Planning), Kunming, 2012: 160-168.]Search in Google Scholar
[[42] Zhou Xiaofan, Li Shengcai, Zhang Yufang. Reliability analysis of seismic function of urban water supply network[J]. Journal of Zhengzhou University of Light Industry, 2012, 27(1): 49-52.]Search in Google Scholar
[[43] Liu Wei, Xu Liang, Li Jie. Research on the Seismic Topology Optimization Algorithm of Water Supply Network[J]. Science China (Technical Science), 2012, 42(11): 1351-1360.]Search in Google Scholar
[[44] National Standards of the People’s Republic of China. Classification of Earthquake Damage Levels for Lifeline Engineering (GB/T24336-2009) [S]. Beijing: China Standards Press, 2009.]Search in Google Scholar
[[45] Prasad TD, Park NS. Multiobjective genetic algorithms for design of water distribution networks[J]. J Water Resour Plan Manag ASCE, 2004, 130(1):73-82.]Search in Google Scholar
[[46] Jayaram N, Srinivasan K. Performance-based optimal design and rehabilitation of water distribution networks using life cycle costing[J]. Water Resour Res, 2008, 44(1): W01, 417. doi:10.1029/2006WR005316.]Search in Google Scholar
[[47] Tierney K,Trainor J.Networks and resilience in the world trade center disaster [R]. NY:MCEER,2004.]Search in Google Scholar
[[48] Cagnan Z, Davidson R. Discrete event simulation of the post-earthquake restoration process for electric power systems[J]. Int.J.of Risk Assessment and Management, 2007, 7(8):1138-1156.]Search in Google Scholar
[[49] Scawthorn C, O’Rourke T D, Blackburn F T. The 1906 San Francisco earthquake and fire-enduring lessons for fire protection and water supply[J]. Earthquake Spectra, 2006, 22(S2):135-158.]Search in Google Scholar
[[50] O’Rourke T D. Critical infrastructure, inter dependencies, and resilience[J]. The Bridge, 2007, Spring:23-29.]Search in Google Scholar
[[51] Cimellaro G P, Reinhorn A M. Seismic resilience of a hospital system[J]. Structure and Infrastructure Engineering: Maintenance, Management, Life-Cycle Design and Performance, 2010, 6(1/2):127-144.]Search in Google Scholar
[[52] Cutter S L, Burton C G, Emrich C T. Disaster resilience indicators for bench marking baseline conditions[J]. Journal of Homeland Security and Emergency Management, 2010, 7(1):147-155.]Search in Google Scholar
[[53] Susan A B, Rachel A D, Taronne H P T. Strategies to reduce duration of post-earthquake water service interruptions in Los Angeles[J]. Structure and Infrastructure Engineering, 2012, 8(2):199-210.]Search in Google Scholar
[[54] Jonas J, Rajib S, Yukiko T, et al. Assessing community resilience to climate-related disasters in Chennai, India[J]. International Journal of Disaster Risk Reduction, 2012, 1:44-54.]Search in Google Scholar
[[55] Guo Y. Urban resilience in post-disaster reconstruction: Towards a resilient development in Sichuan, China[J]. Int.J.Disaster Risk Sci, 2012, 3(1):45-55.]Search in Google Scholar
[[56] Wu Jidong, Li Ning, Ji Zhonghui, etc. Disaster recovery metrics and recovery models [C]//Nanjing: Innovative theories and methods for risk analysis and crisis response-The fifth year of the Risk Analysis Professional Committee of China Disaster Defense Association Conference Proceedings, 2012: 627-632.]Search in Google Scholar
[[57] Pedcris M O, Mashahiko F. A localized disaster-resilience index to assess coastal communities based on analytic hierarchy process(AHP)[J]. International Journal of Disaster Risk Reduction, 2013, 3:62-75.]Search in Google Scholar
[[58] Rossman LA. Epanet users manual[C]//Report EPA/600/R-00/057, National Risk Management Research Laboratory, 2000.]Search in Google Scholar
[[59] Miles S B, Chang S E. Modeling community recovery from earthquake[J]. Earthquake Spectra, 2006, 22(2):439-458.]Search in Google Scholar
[[60] Chang S E, McDaniels T, Longstaff H. Fostering disaster resilience through addressing infrastructure inter dependencies[J]. Plan Canada, 2006, 46(4):33-36.]Search in Google Scholar
