论文信息 - Predicting Takeover Quality in Conditionally Automated Vehicles Using Machine Learning and Genetic Algorithms

Predicting Takeover Quality in Conditionally Automated Vehicles Using Machine Learning and Genetic Algorithms

Takeover requests in conditionally automated vehicles are a critical point in time that can lead to accidents, and as such should be transmitted with care. Currently, several studies have shown the impact of using different modalities for different psychophysiological states, but no model exists to predict the takeover quality depending on the psychophysiological state of the driver and takeover request modalities. In this paper, we propose a machine learning model able to predict the maximum steering wheel angle and the reaction time of the driver, two takeover quality metrics. Our model is able to achieve a gain of 42.26% on the reaction time and 8.92% on the maximum steering wheel angle compared to our baseline. This was achieved using up to 150 s of psychophysiological data prior to the takeover. Impacts of using such a model to choose takeover modalities instead of using standard takeover requests should be investigated.

[1] Christian Günter Gold,et al. Modeling of Take-Over Performance in Highly Automated Vehicle Guidance , 2016 .

[2] Nadja Schömig,et al. Secondary task engagement and disengagement in the context of highly automated driving , 2018, Transportation Research Part F: Traffic Psychology and Behaviour.

[3] Fouad Hadj-Selem,et al. How different mental workload levels affect the take-over control after automated driving , 2016, 2016 IEEE 19th International Conference on Intelligent Transportation Systems (ITSC).

[4] Frank E. Pollick,et al. Language-based multimodal displays for the handover of control in autonomous cars , 2015, AutomotiveUI.

[5] Klaus Bengler,et al. Taking Over Control From Highly Automated Vehicles in Complex Traffic Situations , 2016, Hum. Factors.

[6] Klaus Bengler,et al. Effects of Task-Induced Fatigue in Prolonged Conditional Automated Driving , 2019, Hum. Factors.

[7] Benjamin Recht,et al. Weighted Sums of Random Kitchen Sinks: Replacing minimization with randomization in learning , 2008, NIPS.

[8] Jan C. Brammer,et al. NeuroKit2: A Python toolbox for neurophysiological signal processing. , 2021, Behavior research methods.

[9] Randal S. Olson,et al. Automating Biomedical Data Science Through Tree-Based Pipeline Optimization , 2016, EvoApplications.

[10] Elena Mugellini,et al. Owner Manuals Review and Taxonomy of ADAS Limitations in Partially Automated Vehicles , 2019, AutomotiveUI.