Seismic Loss Estimates For A Hypothetical Water System

Topics in this volume include calculating seismic risk, replacement cost estimation procedures, methods for developing component loss algorithms and applications of loss algorithm methods to demonstration water system components.

Presents a collection of papers presented at the 1990 Annual Civil Engineering Convention and Exposition in California. This work summarizes seismic loss and reliability analysis methods for complex spatially distributed lifeline systems. It emphasises on methods for direct loss estimation rather than on down time and other indirect losses.

This book deals with earthquake-resistant structures, such as, buildings, bridges and liquid storage tanks. It contains twenty chapters covering several interesting research topics written by researchers and experts in the field of earthquake engineering. The book covers seismic-resistance design of masonry and reinforced concrete structures to be constructed as well as safety assessment, strengthening and rehabilitation of existing structures against earthquake loads. It also includes three chapters on electromagnetic sensing techniques for health assessment of structures, post earthquake assessment of steel buildings in fire environment and response of underground pipes to blast loads. The book provides the state-of-the-art on recent progress in earthquake-resistant structures. It should be useful to graduate students, researchers and practicing structural engineers.

SYNER-G, a multidisciplinary effort funded by the European Union, allowed the development of an innovative methodological framework for the assessment of physical as well as socio-economic seismic vulnerability and risk at urban and regional level. The results of SYNER-G are presented in two books both published by Springer, the present and a second one, entitled “SYNER-G: Typology Definition and Fragility Functions for Physical Elements at Seismic Risk: Buildings, Lifelines, Transportation Networks and Critical Facilities”(*), which provides a comprehensive state-of-the-art of the fragility curves, an alternative way to express physical vulnerability of elements at risk. In this second volume of SYNER-G, the focus has been on presenting a unified holistic methodology for assessing vulnerability at systems level considering interactions between elements at risk (physical and non-physical) and between different systems. The proposed methodology and tool encompasses in an integrated fashion all aspects in the chain, from hazard to the vulnerability assessment of components and systems and to the socio-economic impacts of an earthquake, accounting for most relevant uncertainties within an efficient quantitative simulation scheme. It systematically integrates the most advanced fragility functions to assess the vulnerability of physical assets for buildings, utility systems, transportation networks and complex infrastructures such as harbours and hospitals. The increasing impact due to interactions between different components and systems is treated in a comprehensive way, providing specifications for each network and infrastructure. The proposed socio-economic model integrates social vulnerability into the physical systems modelling approaches providing to decision makers with a dynamic platform to capture post disaster emergency issues like shelter demand and health impact decisions. Application examples at city and regional scale have provided the necessary validation of the methodology and are also included in the book. The present volume, with its companion volume on fragility functions, represent a significant step forward in the seismic vulnerability and risk assessment of complex interacting urban and regional systems and infrastructures. These volumes are not only of interest to scientists and engineers but also to the insurance industry, decision makers and practitioners in the sector of civil protection and seismic risk management. (*) Pitilakis K, Crowley E, Kaynia A (eds) (2014) SYNER-G: Typology definition and fragility functions for physical elements at seismic risk, Series: Geotechnical, Geological and Earthquake Engineering 27, ISBN 978-94-007-7872-6, Springer Science+Business Media, Dordrecht.

Prepared by the Technical Council on Lifeline Earthquake Engineering of ASCE This TCLEE Monograph provides guidelines for the seismic evaluation and upgrade of water transmission facilities, including aqueducts, tunnels, canals, buried pipelines, elevated pipelines and their appurtenances. Topics covered include the performance of these facilities in past earthquakes; geotechnical issues; performance criteria; risk analysis; analysis methods; and a series of case studies. The guidelines can also be used for the design of new water transmission facilities. The case studies cover seismic designs and retrofits for the Mokelumne Aqueduct, the Contra Costa Canal, the Borel Canal, buried pipes at fault crossings, and auxiliary water fire fighting systems. The case studies also examine post-earthquake operations, financial issues, and the benefits of seismic retrofits.

This book introduces the concepts of Resilience-Based Design (RBD) as an extension of Performance-Based Design. It provides readers with a range of cutting-edge methodologies for evaluating resilience and clarifies the difference between resilience, vulnerability and sustainability. Initially, the book focuses on describing the different types of uncertainty that arise in the context of resilience evaluation. This is followed by an entire chapter dedicated to the analytical and experimental recovery functions. Then, starting from the definition of resilience provided by MCEER, an extension of the methodology is provided that introduces the seven dimensions of Community Resilience, summarized in the acronym PEOPLES. They are: Population and Demographics, Environmental/Ecosystem, Organized Governmental Services, Physical infrastructures, Lifestyle and Community Competence, Economic Development, and Socio-Cultural Capital. For each dimension, components and subcomponents are defined and the related indices are provided. Underlining the importance of the physical infrastructure dimension, the book provides several examples of applications for transportation, hydraulic, gas and power networks. The problem of interdependencies and the domino effect is also taken into account during the analysis. One of the book’s closing chapters focuses on different methodologies for improving disaster preparedness and engineering mitigation strategies, while the last chapter describes the different computer platforms available on the market for evaluating Community Resilience. The book offers readers an extensive introduction to the concept of Resilience-Based Design, together with selected advanced applications for specialists. No prerequisite knowledge is needed in order to understand the book, and the Appendix offers valuable supplemental information on e.g. the probabilistic concepts. As such, the book offers a valuable resource for graduate students, young engineers and researchers who are interested in the topic, and can also be used as a supplementary text in graduate level Disaster Resilience courses.