Supporting Advances in Human-Systems Coordination through Simulation of Diverse, Distributed Expertise

Nyre-Yu, Megan; Caldwell, Barrett S.

doi:10.3390/systems6040039

Cited by 3 publications

(1 citation statement)

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“…Moreover, these methods can accommodate experimental research in human-automation teaming by creating virtual teams from real team data and testing different attribute levels and combinations in a simulated environment. Though only a prototype of how ABM simulation methods can explore this area, the research paves a path to studying complex sociotechnical systems through computational approaches, more specifically in how components of a team (human-human, human-robot, or robot-robot) work together to complete a task [41]. This type of research also allows for experimentation in dynamic function allocation and how it affects overall performance.…”

Section: Human-automation Team Design Using Simulationmentioning

confidence: 99%

Advances in Human-Automation Collaboration, Coordination and Dynamic Function Allocation

Caldwell¹,

Nyre-Yu²,

Hill³

2019

Advances in Transdisciplinary Engineering

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Effective integration of humans and automation in control systems engineering has been an ongoing effort since the original publication of McRuer’s descriptions of human operators in servomechanism systems in 1959. Over the past 60 years, increasing capabilities of automation and computer systems have resulted in changing considerations of function allocation and human-automation interaction since Fitts’ “Humans are better at / Machines are better at” descriptions of the early 1950s. The processes of distributed autonomy and dynamic function allocation in modern human-automation and human-robotic interactions benefit from increased computing capabilities, resulting in systems with potentially fluid (and sometimes conflicting) boundaries for human vs. automation control. Using examples from human and robotic spaceflight, robotics can demonstrate significant autonomy (automated “safe-moding” and restart by Mars rovers), and humans may have limited autonomy (when astronauts conducting extravehicular activity rely on and wait for ground controllers to create or modify procedures to complete required tasks). Proposed future advances in human-automation interaction and coordination include the development of “centaur” teams of humans interacting with sophisticated software and robotic agents as team members (rather than fixed allocations as human-controlled servos or automation-controlled autonomous systems). Approaches within the authors’ lab include qualitative research of process and cognitive task demands to create functional architecture for AI applications in cyber security. Another method uses agent-based modeling to incorporate individual thinking style and interpersonal interactions in task performance simulations, effectively creating more robust hybrid systems incorporating cognitive and social factors in complex settings.

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Section: Human-automation Team Design Using Simulationmentioning

confidence: 99%