Alternative metrics for evaluating the resilence of advanced life support systems
Ensuring the safety of the crew is a key performance requirement of a life support system. However, a number of conceptual and practical difficulties arise when devising metrics to concretely measure the ability of a life support system to maintain critical functions in the presence of anticipated a...
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| Veröffentlicht in: | Scientific and technical aerospace reports 2004-02, Vol.42 (4) |
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| creator | Bell, Ann Maria Dearden, Richard Levri, Julie A |
| description | Ensuring the safety of the crew is a key performance requirement of a life support system. However, a number of conceptual and practical difficulties arise when devising metrics to concretely measure the ability of a life support system to maintain critical functions in the presence of anticipated and unanticipated faults. Resilience is a dynamic property of a life support system that depends on the complex interactions between faults, controls and system hardware. We review some of the approaches to understanding the robustness or resilience of complex systems being developed in diverse fields such as ecology, software engineering and cell biology and discuss their applicability to regenerative life support systems. We also consider how approaches to measuring resilience vary depending on system design choices such as the definition and choice of the nominal operating regime. Finally, we explore data collection and implementation issues such as the key differences between the instantaneous or conditional and average or overall measures of resilience. Extensive simulation of a hybrid computational model of a water revitalization subsystem (WRS) with probabilistic, component-level faults provides data about off-nominal behavior of the system. The data are used to consider alternative measures of resilience as predictors of the system's ability to recover from component-level faults. |
| format | Article |
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Extensive simulation of a hybrid computational model of a water revitalization subsystem (WRS) with probabilistic, component-level faults provides data about off-nominal behavior of the system. The data are used to consider alternative measures of resilience as predictors of the system's ability to recover from component-level faults.</abstract></addata></record> |
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| identifier | ISSN: 1548-8837 |
| ispartof | Scientific and technical aerospace reports, 2004-02, Vol.42 (4) |
| issn | 1548-8837 |
| language | eng |
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| source | U.S. Government Documents; Alma/SFX Local Collection |
| title | Alternative metrics for evaluating the resilence of advanced life support systems |
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