Effects of forward collision warning and repeated event exposure on emergency braking

► Effects of FCW, repeated events and time headway on response times were examined. ► The effect of FCW depended strongly on both repeated exposure and time headway. ► This raises several methodological issues for the design of driver warning studies. ► The implementation of event exposure and criti...

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Published inTransportation research. Part F, Traffic psychology and behaviour Vol. 18; pp. 34 - 46
Main Authors Aust, Mikael Ljung, Engström, Johan, Viström, Matias
Format Journal Article
LanguageEnglish
Published Elsevier India Pvt Ltd 01.05.2013
Subjects
Brake response time
Braking
Collision avoidance
Driver distraction
driver response
Emergencies
Emergency warning programs
Forward collision warning
Headways
Repeated measures rear-end
Repeated measures rear-end crashes
Response time
Safety margins
Simulator event design
systems
trust
Vehicles
visual control
Warning
Driver distraction
Simulator event design
Forward collision warning
Brake response time
Repeated measures rear-end crashes
Online AccessGet full text
ISSN1369-8478
1873-5517
DOI10.1016/j.trf.2012.12.010

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Abstract ► Effects of FCW, repeated events and time headway on response times were examined. ► The effect of FCW depended strongly on both repeated exposure and time headway. ► This raises several methodological issues for the design of driver warning studies. ► The implementation of event exposure and criticality is a key result determinant. Many experimental studies use repeated lead vehicle braking events to study the effects of forward collision warning (FCW) systems. It can, however, be argued that the use of repeated events induce expectancies and anticipatory behaviour that may undermine validity in terms of generalisability to real-world, naturalistic, emergency braking events. The main objective of the present study was to examine to what extent the effect of FCW on response performance is moderated by repeated exposure to a critical lead vehicle braking event. A further objective was to examine if these effects depended on event criticality, here defined as the available time headway when the lead vehicle starts to brake. A critical lead vehicle braking event was implemented in a moving-base simulator. The effects of FCW, repeated event exposure and initial time headway on driver response times and safety margins were examined. The results showed that the effect of FCW depended strongly on both repeated exposure and initial time headway. In particular, no effects of FCW were found for the first exposure, while strong effects occurred when the scenario was repeated. This was interpreted in terms of a switch from closed-loop responses triggered reactively by the situation, towards an open-loop strategy where subjects with FCW responded proactively directly to the warning. It was also found that initial time headway strongly determined response times in closed-loop conditions but not in open-loop conditions. These results raise a number of methodological issues pertaining to the design of experimental studies with the aim of evaluating the effects of active safety systems. In particular, the implementation of scenario exposure and criticality must be carefully considered.
AbstractList Many experimental studies use repeated lead vehicle braking events to study the effects of forward collision warning (FCW) systems. It can, however, be argued that the use of repeated events induce expectancies and anticipatory behaviour that may undermine validity in terms of generalisability to real-world, naturalistic, emergency braking events. The main objective of the present study was to examine to what extent the effect of FCW on response performance is moderated by repeated exposure to a critical lead vehicle braking event. A further objective was to examine if these effects depended on event criticality, here defined as the available time headway when the lead vehicle starts to brake. A critical lead vehicle braking event was implemented in a moving-base simulator. The effects of FCW, repeated event exposure and initial time headway on driver response times and safety margins were examined. The results showed that the effect of FCW depended strongly on both repeated exposure and initial time headway. In particular, no effects of FCW were found for the first exposure, while strong effects occurred when the scenario was repeated. This was interpreted in terms of a switch from closed-loop responses triggered reactively by the situation, towards an open-loop strategy where subjects with FCW responded proactively directly to the warning. It was also found that initial time headway strongly determined response times in closed-loop conditions but not in open-loop conditions. These results raise a number of methodological issues pertaining to the design of experimental studies with the aim of evaluating the effects of active safety systems. In particular, the implementation of scenario exposure and criticality must be carefully considered.
► Effects of FCW, repeated events and time headway on response times were examined. ► The effect of FCW depended strongly on both repeated exposure and time headway. ► This raises several methodological issues for the design of driver warning studies. ► The implementation of event exposure and criticality is a key result determinant. Many experimental studies use repeated lead vehicle braking events to study the effects of forward collision warning (FCW) systems. It can, however, be argued that the use of repeated events induce expectancies and anticipatory behaviour that may undermine validity in terms of generalisability to real-world, naturalistic, emergency braking events. The main objective of the present study was to examine to what extent the effect of FCW on response performance is moderated by repeated exposure to a critical lead vehicle braking event. A further objective was to examine if these effects depended on event criticality, here defined as the available time headway when the lead vehicle starts to brake. A critical lead vehicle braking event was implemented in a moving-base simulator. The effects of FCW, repeated event exposure and initial time headway on driver response times and safety margins were examined. The results showed that the effect of FCW depended strongly on both repeated exposure and initial time headway. In particular, no effects of FCW were found for the first exposure, while strong effects occurred when the scenario was repeated. This was interpreted in terms of a switch from closed-loop responses triggered reactively by the situation, towards an open-loop strategy where subjects with FCW responded proactively directly to the warning. It was also found that initial time headway strongly determined response times in closed-loop conditions but not in open-loop conditions. These results raise a number of methodological issues pertaining to the design of experimental studies with the aim of evaluating the effects of active safety systems. In particular, the implementation of scenario exposure and criticality must be carefully considered.
Author Aust, Mikael Ljung
Engström, Johan
Viström, Matias
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  surname: Aust
  fullname: Aust, Mikael Ljung
  email: mikael.ljung.aust@volvocars.com
  organization: SAFER – Vehicle and Traffic Safety Centre at Chalmers University of Technology, Volvo Cars Safety Centre, Volvo Car Corporation, SE-405 31 Göteborg, Sweden
– sequence: 2
  givenname: Johan
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  organization: Safer – Vehicle and Traffic Safety Centre at Chalmers University of Technology, Göteborg, Sweden
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  givenname: Matias
  surname: Viström
  fullname: Viström, Matias
  organization: Safer – Vehicle and Traffic Safety Centre at Chalmers University of Technology, Göteborg, Sweden
BackLink https://research.chalmers.se/publication/177689$$DView record from Swedish Publication Index
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Keywords Driver distraction
Simulator event design
Forward collision warning
Brake response time
Repeated measures rear-end crashes
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Snippet ► Effects of FCW, repeated events and time headway on response times were examined. ► The effect of FCW depended strongly on both repeated exposure and time...
Many experimental studies use repeated lead vehicle braking events to study the effects of forward collision warning (FCW) systems. It can, however, be argued...
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StartPage 34
SubjectTerms Brake response time
Braking
Collision avoidance
Driver distraction
driver response
Emergencies
Emergency warning programs
Forward collision warning
Headways
Repeated measures rear-end
Repeated measures rear-end crashes
Response time
Safety margins
Simulator event design
systems
trust
Vehicles
visual control
Warning
Title Effects of forward collision warning and repeated event exposure on emergency braking
URI https://dx.doi.org/10.1016/j.trf.2012.12.010
https://www.proquest.com/docview/1464587363
https://www.proquest.com/docview/1718920875
https://research.chalmers.se/publication/177689
Volume 18
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