Presentation
A Queuing Model Based Rapid Evaluation Method for Automotive Control Design
DescriptionObjective:This paper evaluates the ergonomics performance of automotive driving systems through a novel computational model, aiming to enhance vehicle control design more cost-effectively than traditional experimental human factors research in the automotive field.
Methods: Parameters such as spatial coordinates and control dimensions were measured for different driver interaction controls (e.g., hazard light switches, steering wheel buttons) across three typical passenger vehicles. These parameters were integrated into the QN-MHP-U model to simulate driver operational behaviors and predict task performance. A computational method was introduced to assess the ergonomic scores of automotive control designs based on the modeling results.
Conclusion:The QN-MHP-U model provides a systematic and universally applicable solution for evaluating and comparing vehicle control designs within automotive driving systems. This allows automotive designers to assess and improve vehicle control designs from an ergonomic perspective more efficiently in terms of time and economic costs.
Methods: Parameters such as spatial coordinates and control dimensions were measured for different driver interaction controls (e.g., hazard light switches, steering wheel buttons) across three typical passenger vehicles. These parameters were integrated into the QN-MHP-U model to simulate driver operational behaviors and predict task performance. A computational method was introduced to assess the ergonomic scores of automotive control designs based on the modeling results.
Conclusion:The QN-MHP-U model provides a systematic and universally applicable solution for evaluating and comparing vehicle control designs within automotive driving systems. This allows automotive designers to assess and improve vehicle control designs from an ergonomic perspective more efficiently in terms of time and economic costs.
Event Type
Industry/Practitioner Case Study
Lecture
TimeFriday, September 13th9:45am - 10:05am MST
LocationFLW Salon G
Surface Transportation