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Citation |
Miao F, Ghosn M. Struct. Saf. 2016; 63: 33-46. |
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Copyright |
(Copyright © 2016, Elsevier Publishing) |
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DOI |
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PMID |
unavailable |
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Abstract |
Structural systems optimized to meet member design criteria as specified in current design standards and specifications may not provide sufficient levels of robustness to withstand a possible local failure following an unforeseen extreme event. In fact, the failure of one structural element may result in the failure of another creating a chain reaction that might progress throughout the entire structure or a major portion of it leading to catastrophic collapse. To reduce the chances of such collapses, the U.S. General Services Administration (GSA) established a set of procedures and criteria to evaluate the robustness of buildings using traditional deterministic methods. Although widely accepted and used for the progressive collapse analysis of buildings, the GSA criteria may not be suitable for bridges because of the differences in their structural configurations and in the nature and intensity of their permanent and transient loads. Furthermore, it is not clear how the existing criteria take into consideration the large uncertainties associated with estimating the applied loads and the capacity of structural systems to resist collapse following the initiation of a local failure. Because performing direct probabilistic analyses may be impractical for routine engineering practice, following current code calibration processes, design guidelines and standards can specify incremental progressive collapse analysis criteria that are calibrated based on structural reliability concepts to ensure consistent levels of safety for the pertinent range of applications, load levels and structural types and configurations. Language: en |