TY - JOUR
T1 - State-based modeling of continuous human-integrated systems
T2 - An application to air traffic separation assurance
AU - Landry, Steven J.
AU - Lagu, Amit
AU - Kinnari, Jouko
N1 - Funding Information:
This research was materially supported by NASA Ames Research Center under cooperative agreement NNA06CN25A . The technical monitor for the work is Russ Paielli. The opinions in this paper are those of the author alone; NASA had no involvement in the study design, analysis and interpretation, writing, or decision to submit the paper. I also would like to indicate my appreciation for the thoughtful comments of the reviewers, which contributed to the quality of the final paper.
PY - 2010/4
Y1 - 2010/4
N2 - A method for modeling the safety of human-integrated systems that have continuous dynamics is introduced. The method is intended to supplement more detailed reliability-based methods. Assumptions for the model are defined such that the model is demonstrably complete, enabling it to yield a set of key agent characteristics. These key characteristics identify a sufficient set of characteristics that can be used to establish the safety of particular system configurations. The method is applied for the analysis of the safety of strategic and tactical separation assurance algorithms for the next generation air transportation system. It is shown that the key characteristics for this problem include the ability of agents (human or automated) to identify configurations that can enable intense transitions from a safe to unsafe state. However, the most technologically advanced algorithm for separation assurance does not currently attempt to identify such configurations. It is also discussed how, although the model is in a form that lends itself to quantitative evaluations, such evaluations are complicated by the difficulty of accurately quantifying human error probabilities.
AB - A method for modeling the safety of human-integrated systems that have continuous dynamics is introduced. The method is intended to supplement more detailed reliability-based methods. Assumptions for the model are defined such that the model is demonstrably complete, enabling it to yield a set of key agent characteristics. These key characteristics identify a sufficient set of characteristics that can be used to establish the safety of particular system configurations. The method is applied for the analysis of the safety of strategic and tactical separation assurance algorithms for the next generation air transportation system. It is shown that the key characteristics for this problem include the ability of agents (human or automated) to identify configurations that can enable intense transitions from a safe to unsafe state. However, the most technologically advanced algorithm for separation assurance does not currently attempt to identify such configurations. It is also discussed how, although the model is in a form that lends itself to quantitative evaluations, such evaluations are complicated by the difficulty of accurately quantifying human error probabilities.
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U2 - 10.1016/j.ress.2009.11.004
DO - 10.1016/j.ress.2009.11.004
M3 - Article
AN - SCOPUS:75949104880
SN - 0951-8320
VL - 95
SP - 345
EP - 353
JO - Reliability Engineering and System Safety
JF - Reliability Engineering and System Safety
IS - 4
ER -