Procedures in complex systems: the airline cockpit

In complex human-machine systems, successful operations depend on an elaborate set of procedures which are specified by the operational management of the organization. These procedures indicate to the human operator (in this case the pilot) the manner in which operational management intends to have...

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Published in:IEEE transactions on systems, man and cybernetics. Part A, Systems and humans man and cybernetics. Part A, Systems and humans, 1997-05, Vol.27 (3), p.302-312
Main Authors: Degani, A., Wiener, E.L.
Format: Article
Language:English
Subjects:
Accidents, Aviation - prevention & control
Aerospace control
Aerospace Medicine
Asset management
Automation
Aviation - methods
Aviation - organization & administration
Aviation - standards
Decision Making
Ergonomics
Face recognition
Humans
Man machine systems
Manufacturing processes
Military aircraft
Models, Organizational
NASA
Policy Making
Process control
Safety
Space life sciences
Task Performance and Analysis
Workload
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cited_by cdi_FETCH-LOGICAL-c428t-8e5ec63060bb0bf6940b4e05820b7bdd4d3a26e713bbd34bcfcd861c953fd1c93
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container_title IEEE transactions on systems, man and cybernetics. Part A, Systems and humans
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creator Degani, A.
Wiener, E.L.
description In complex human-machine systems, successful operations depend on an elaborate set of procedures which are specified by the operational management of the organization. These procedures indicate to the human operator (in this case the pilot) the manner in which operational management intends to have various tasks done. The intent is to provide guidance to the pilots and to ensure a safe, logical, efficient, and predictable (standardized) means of carrying out the objectives of the job. However, procedures can become a hodge-podge. Inconsistent or illogical procedures may lead to noncompliance by operators. Based on a field study with three major airlines, the authors propose a model for procedure development called the "Four P's": philosophy, policies, procedures, and practices. Using this model as a framework, the authors discuss the intricate issue of designing flight-deck procedures, and propose a conceptual approach for designing any set of procedures. The various factors, both external and internal to the cockpit, that must be considered for procedure design are presented. In particular, the paper addresses the development of procedures for automated cockpits-a decade-long, and highly controversial issue in commercial aviation. Although this paper is based on airline operations, we assume that the principles discussed here are also applicable to other high-risk supervisory control systems, such as space flight, manufacturing process control, nuclear power production, and military operations.
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source IEEE Electronic Library (IEL) Journals
subjects Accidents, Aviation - prevention & control
Aerospace control
Aerospace Medicine
Asset management
Automation
Aviation - methods
Aviation - organization & administration
Aviation - standards
Decision Making
Ergonomics
Face recognition
Humans
Man machine systems
Manufacturing processes
Military aircraft
Models, Organizational
NASA
Policy Making
Process control
Safety
Space life sciences
Task Performance and Analysis
Workload
title Procedures in complex systems: the airline cockpit
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