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200 00$aProceedings of the fourth Resilience engineering symposium : 8-10 June, 2011, Sophia Antipolis, France
210   $cPresses des Mines$d2011
210 31$a[Place of publication not identified]$cPresses des mines$d2011
215   $a1 online resource (284 pages)
225 1 $aCollection Sciences E?conomiques
300   $aBibliographic Level Mode of Issuance: Monograph
311   $a2-911256-47-6 
330   $aThese proceedings document the various presentations at the Fourth Resilience Engineering Symposium held on June 8-10, 2011, in Sophia-Antipolis, France. The Symposium gathered participants from five continents and provided them with a forum to exchange experiences and problems, and to learn about Resilience Engineering from the latest scientific achievements to recent practical applications. The First Resilience Engineering Symposium was held in Söderköping, Sweden, on October 25-29 2004. The Second Resilience Engineering Symposium was held in Juan-les-Pins, France, on November 8-10 2006, The Third Resilience Engineering Symposium was held in Juan-les-Pins, France, on October 28-30 2008. Since the first Symposium, resilience engineering has fast become recognised as a valuable complement to the established approaches to safety. Both industry and academia have recognised that resilience engineering offers valuable conceptual and practical basis that can be used to attack the problems of interconnectedness and intractability of complex socio-technical systems. The concepts and principles of resilience engineering have been tested and refined by applications in such fields as air traffic management, offshore production, patient safety, and commercial fishing. Continued work has also made it clear that resilience is neither limited to handling threats and disturbances, nor confined to situations where something can go wrong. Today, resilience is understood as the intrinsic ability of a system to adjust its functioning prior to, during, or following changes and disturbances, so that it can sustain required operations under both expected and unexpected conditions. This definition emphasizes the ability to continue functioning, rather than simply to react and recover from disturbances and the ability to deal with diverse conditions of functioning, expected as well as unexpected. For anyone who is interested in learning more about Resilience Engineering, the books?
410  0$aCollection Sciences e?conomiques.
606   $aMechanical Engineering$2HILCC
606   $aEngineering & Applied Sciences$2HILCC
606   $aIndustrial & Management Engineering$2HILCC
610   $amanagement
610   $aengineering
610   $atechnology
610   $ahealth care
610   $atechnical systems
615  7$aMechanical Engineering
615  7$aEngineering & Applied Sciences
615  7$aIndustrial & Management Engineering
700   $aErik Hollnagel$b Éric Rigaud, Denis Besnard (dir.)$4auth$01357021
702   $aHollnagel$b Erik
702   $aBesnard$b Denis
702   $aRigaud$b Éric
801  0$bPQKB
906   $aBOOK
912   $a9910133352303321
996   $aProceedings of the fourth Resilience engineering symposium : 8-10 June, 2011, Sophia Antipolis, France$93362328
997   $aUNINA