Haptic Feedback of Front Vehicle Motion May Improve Driving Control

Xiaoxiao Cheng; Xianzhe Geng; Yanpei Huang; Etienne Burdet

doi:10.1109/LRA.2024.3502063

Haptic Feedback of Front Vehicle Motion May Improve Driving Control

Xiaoxiao Cheng^*, Xianzhe Geng, Yanpei Huang, Etienne Burdet

^*Corresponding author for this work

EEE - Academic & Research

Research output: Contribution to journal › Article › peer-review

Abstract

This study investigates the role of haptic feedback in a two vehicles following scenario, where information about the motion of the front vehicle is provided through a virtual elastic connection with it. Using a robotic interface in a simulated driving environment, we examined the impact of varying levels of such haptic feedback on the driver's ability to follow the road while avoiding obstacles. The results of an experiment with 15 subjects indicate that haptic feedback from the front vehicle's motion can significantly improve driving control (i.e., reduce motion jerk and deviation from the road) and reduce mental load (evaluated via questionnaire). This suggests that haptic communication, as observed between physically interacting humans, can be leveraged to improve safety and efficiency in automated driving systems, warranting further testing in real driving scenarios.

Original language	English
Journal	IEEE Robotics and Automation Letters
Volume	10
Issue number	1
Early online date	19 Nov 2024
DOIs	https://doi.org/10.1109/LRA.2024.3502063
Publication status	Published - Jan 2025

Keywords

haptics and haptic interfaces
Human performance augmentation
human-robot collaboration

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10.1109/LRA.2024.3502063

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title = "Haptic Feedback of Front Vehicle Motion May Improve Driving Control",

abstract = "This study investigates the role of haptic feedback in a two vehicles following scenario, where information about the motion of the front vehicle is provided through a virtual elastic connection with it. Using a robotic interface in a simulated driving environment, we examined the impact of varying levels of such haptic feedback on the driver's ability to follow the road while avoiding obstacles. The results of an experiment with 15 subjects indicate that haptic feedback from the front vehicle's motion can significantly improve driving control (i.e., reduce motion jerk and deviation from the road) and reduce mental load (evaluated via questionnaire). This suggests that haptic communication, as observed between physically interacting humans, can be leveraged to improve safety and efficiency in automated driving systems, warranting further testing in real driving scenarios.",

keywords = "haptics and haptic interfaces, Human performance augmentation, human-robot collaboration",

author = "Xiaoxiao Cheng and Xianzhe Geng and Yanpei Huang and Etienne Burdet",

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AU - Cheng, Xiaoxiao

AU - Geng, Xianzhe

AU - Huang, Yanpei

AU - Burdet, Etienne

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N2 - This study investigates the role of haptic feedback in a two vehicles following scenario, where information about the motion of the front vehicle is provided through a virtual elastic connection with it. Using a robotic interface in a simulated driving environment, we examined the impact of varying levels of such haptic feedback on the driver's ability to follow the road while avoiding obstacles. The results of an experiment with 15 subjects indicate that haptic feedback from the front vehicle's motion can significantly improve driving control (i.e., reduce motion jerk and deviation from the road) and reduce mental load (evaluated via questionnaire). This suggests that haptic communication, as observed between physically interacting humans, can be leveraged to improve safety and efficiency in automated driving systems, warranting further testing in real driving scenarios.

AB - This study investigates the role of haptic feedback in a two vehicles following scenario, where information about the motion of the front vehicle is provided through a virtual elastic connection with it. Using a robotic interface in a simulated driving environment, we examined the impact of varying levels of such haptic feedback on the driver's ability to follow the road while avoiding obstacles. The results of an experiment with 15 subjects indicate that haptic feedback from the front vehicle's motion can significantly improve driving control (i.e., reduce motion jerk and deviation from the road) and reduce mental load (evaluated via questionnaire). This suggests that haptic communication, as observed between physically interacting humans, can be leveraged to improve safety and efficiency in automated driving systems, warranting further testing in real driving scenarios.

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JO - IEEE Robotics and Automation Letters

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Haptic Feedback of Front Vehicle Motion May Improve Driving Control

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Keywords

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