Toward a multi-method approach to formalizing human-automation interaction and human-human communications

Breakdowns in complex systems often occur as a result of system elements interacting in ways unanticipated by analysts or designers. The use of task behavior as part of a larger, formal system model is potentially useful for analyzing such problems because it allows the ramifications of different hu...

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Hauptverfasser:	Bass, E. J., Bolton, M. L., Feigh, K., Griffith, D., Gunter, E., Mansky, W., Rushby, J.
Format:	Tagungsbericht
Sprache:	eng
Schlagworte:	Aerospace control Aircraft Analytical models Atmospheric modeling formal verification human-automation interaction human-computer interaction Humans model checking Semantics Syntactics Task analysis theorem proving
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creator	Bass, E. J. Bolton, M. L. Feigh, K. Griffith, D. Gunter, E. Mansky, W. Rushby, J.
description	Breakdowns in complex systems often occur as a result of system elements interacting in ways unanticipated by analysts or designers. The use of task behavior as part of a larger, formal system model is potentially useful for analyzing such problems because it allows the ramifications of different human behaviors to be verified in relation to other aspects of the system. A component of task behavior largely overlooked to date is the role of human-human interaction, particularly human-human communication in complex human-computer systems. We are developing a multi-method approach based on extending the Enhanced Operator Function Model language to address human agent communications (EOFMC). This approach includes analyses via theorem proving and future support for model checking linked through the EOFMC top level XML description. Herein, we consider an aviation scenario in which an air traffic controller needs a flight crew to change the heading for spacing. Although this example, at first glance, seems to be one simple task, on closer inspection we find that it involves local human-human communication, remote human-human communication, multi-party communications, communication protocols, and human-automation interaction. We show how all these varied communications can be handled within the context of EOFMC.
doi_str_mv	10.1109/ICSMC.2011.6083935
format	Conference Proceeding
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The use of task behavior as part of a larger, formal system model is potentially useful for analyzing such problems because it allows the ramifications of different human behaviors to be verified in relation to other aspects of the system. A component of task behavior largely overlooked to date is the role of human-human interaction, particularly human-human communication in complex human-computer systems. We are developing a multi-method approach based on extending the Enhanced Operator Function Model language to address human agent communications (EOFMC). This approach includes analyses via theorem proving and future support for model checking linked through the EOFMC top level XML description. Herein, we consider an aviation scenario in which an air traffic controller needs a flight crew to change the heading for spacing. Although this example, at first glance, seems to be one simple task, on closer inspection we find that it involves local human-human communication, remote human-human communication, multi-party communications, communication protocols, and human-automation interaction. We show how all these varied communications can be handled within the context of EOFMC.</abstract><pub>IEEE</pub><doi>10.1109/ICSMC.2011.6083935</doi><tpages>8</tpages></addata></record>
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subjects	Aerospace control Aircraft Analytical models Atmospheric modeling formal verification human-automation interaction human-computer interaction Humans model checking Semantics Syntactics Task analysis theorem proving
title	Toward a multi-method approach to formalizing human-automation interaction and human-human communications
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