Resolving uncertainty on the fly: modeling adaptive driving behavior as active inference

Engström, Johan; Wei, Ran; McDonald, Anthony D.; Garcia, Alfredo; O'Kelly, Matthew; Johnson, Leif

doi:10.3389/fnbot.2024.1341750

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2024

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Cited by 2 publications

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Evaluation of Human Interaction with Fleets of Automated Vehicles in Dynamic Underground Mining Environments

Mironenko,

Banaee,

Loutfi

2024

Communications in Computer and Information Science

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Evaluation of Human Interaction with Fleets of Automated Vehicles in Dynamic Underground Mining Environments

Mironenko,

Banaee,

Loutfi

2024

Communications in Computer and Information Science

View full text Add to dashboard Cite

Active Inference Models of AV Takeovers: Relating Model Parameters to Trust, Situation Awareness, and Fatigue

Wei,

McDonald,

Mehta

et al. 2024

Hum Factors

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Objective Our objectives were to assess the efficacy of active inference models for capturing driver takeovers from automated vehicles and to evaluate the links between model parameters and self-reported cognitive fatigue, trust, and situation awareness. Background Control transitions between human drivers and automation pose a substantial safety and performance risk. Models of driver behavior that predict these transitions from data are a critical tool for designing safer, human-centered, systems but current models do not sufficiently account for human factors. Active inference theory is a promising approach to integrate human factors because of its grounding in cognition and translation to a quantitative modeling framework. Method We used data from a driving simulation to develop an active inference model of takeover performance. After validating the model’s predictions, we used Bayesian regression with a spike and slab prior to assess substantial correlations between model parameters and self-reported trust, situation awareness, fatigue, and demographic factors. Results The model accurately captured driving takeover times. The regression results showed that increases in cognitive fatigue were associated with increased uncertainty about the need to takeover, attributable to mapping observations to environmental states. Higher situation awareness was correlated with a more precise understanding of the environment and state transitions. Higher trust was associated with increased variance in environmental conditions associated with environmental states. Conclusion The results align with prior theory on trust and active inference and provide a critical connection between complex driver states and interpretable model parameters. Application The active inference framework can be used in the testing and validation of automated vehicle technology to calibrate design parameters to ensure safety.

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Resolving uncertainty on the fly: modeling adaptive driving behavior as active inference

Cited by 2 publications

References 70 publications

Evaluation of Human Interaction with Fleets of Automated Vehicles in Dynamic Underground Mining Environments

Evaluation of Human Interaction with Fleets of Automated Vehicles in Dynamic Underground Mining Environments

Active Inference Models of AV Takeovers: Relating Model Parameters to Trust, Situation Awareness, and Fatigue

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