Keeping the driver in the loop in conditionally automated driving: A perception-action theory approach

•Does keeping the driver in the loop improve take-over behavior at SAE L3 automation?•Drivers’ visual- and manual control exposure during automated driving was varied.•In a simulator, the effect on behavior in critical take-over situations was measured.•Take-over behavior was improved by both visual...

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Veröffentlicht in:	Transportation research. Part F, Traffic psychology and behaviour Traffic psychology and behaviour, 2021-05, Vol.79, p.49-62
Hauptverfasser:	Dillmann, J., den Hartigh, R.J.R., Kurpiers, C.M., Raisch, F.K., de Waard, D., Cox, R.F.A.
Format:	Artikel
Sprache:	eng
Schlagworte:	Adaptive automation Automation Automobile drivers Automobile driving Driver behavior Exposure Function allocation Head-up displays Human-automation interaction Manual control Perception Perception-action Reaction time Time measurement Vehicle automation Visual effects Windshields
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container_title	Transportation research. Part F, Traffic psychology and behaviour
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creator	Dillmann, J. den Hartigh, R.J.R. Kurpiers, C.M. Raisch, F.K. de Waard, D. Cox, R.F.A.
description	•Does keeping the driver in the loop improve take-over behavior at SAE L3 automation?•Drivers’ visual- and manual control exposure during automated driving was varied.•In a simulator, the effect on behavior in critical take-over situations was measured.•Take-over behavior was improved by both visual – and manual control exposure.•The combined effect of these factors was additive. In this paper we investigated if keeping the driver in the perception–action loop during automated driving can improve take-over behavior from conditionally automated driving. To meet this aim, we designed an experiment in which visual exposure (perception) and manual control exposure (action) were manipulated. In a dynamic driving simulator experiment, participants (n = 88) performed a non-driving related task either in a head-up display in the windshield (high visual exposure) or on a head-down display near the gear shift (low visual exposure). While driving, participants were either in an intermittent control-mode with four noncritical take-over situations (high manual control exposure), or in a continuous automation-mode throughout the ride (low manual control exposure). In all conditions, a critical take-over had to be carried out after an approximately 13 min ride. Measurements of take-over behavior showed that only high visual exposure had an effect on hands-on reaction time measurements. Both visual exposure and manual control exposure had small to medium sized main effects on time to system deactivation, the maximum velocity of the steering wheel, and the standard deviation of the steering wheel angle. The combined high visual – and high manual control exposure condition led to 0.55 s faster reaction time and 37% less steering variability in comparison to the worst case low visual – and low manual control exposure condition. Together, results corroborate that maintaining visual exposure and manual control exposure during automated driving can be efficacious and suggest that their positive effects are additive.
doi_str_mv	10.1016/j.trf.2021.03.003
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In this paper we investigated if keeping the driver in the perception–action loop during automated driving can improve take-over behavior from conditionally automated driving. To meet this aim, we designed an experiment in which visual exposure (perception) and manual control exposure (action) were manipulated. In a dynamic driving simulator experiment, participants (n = 88) performed a non-driving related task either in a head-up display in the windshield (high visual exposure) or on a head-down display near the gear shift (low visual exposure). While driving, participants were either in an intermittent control-mode with four noncritical take-over situations (high manual control exposure), or in a continuous automation-mode throughout the ride (low manual control exposure). In all conditions, a critical take-over had to be carried out after an approximately 13 min ride. Measurements of take-over behavior showed that only high visual exposure had an effect on hands-on reaction time measurements. Both visual exposure and manual control exposure had small to medium sized main effects on time to system deactivation, the maximum velocity of the steering wheel, and the standard deviation of the steering wheel angle. The combined high visual – and high manual control exposure condition led to 0.55 s faster reaction time and 37% less steering variability in comparison to the worst case low visual – and low manual control exposure condition. 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subjects	Adaptive automation Automation Automobile drivers Automobile driving Driver behavior Exposure Function allocation Head-up displays Human-automation interaction Manual control Perception Perception-action Reaction time Time measurement Vehicle automation Visual effects Windshields
title	Keeping the driver in the loop in conditionally automated driving: A perception-action theory approach
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