Title
Hybrid human-centric haptic shared control using artificial neural network and model predictive control
Author
Harmankaya, Hüseyin (TU Delft Mechanical, Maritime and Materials Engineering; TU Delft Cognitive Robotics)
Contributor
Shyrokau, B. (mentor) 
Happee, R. (graduation committee)
Pool, D.M. (graduation committee)
Rios Lazcano, A.M. (mentor)
Degree granting institution
Delft University of Technology
Programme
Mechanical Engineering | Vehicle Engineering | Cognitive Robotics
Date
2023-05-17
Abstract
Commercially available Lane Keeping Assist systems fail to consider the driver's intentions since they mainly focus on minimising path tracking errors, resulting in conflicts between humans and automation. This often leads to users being unsatisfactory and turning off the assist, as a result diminishing the advantages such as reduced workload and increased road safety. Considering a driver model in the assist helps increase user acceptance. Therefore, we propose a torque-based hybrid controller for a human-centric haptic shared Lane Keeping Assist, pairing a data-driven driver model with a model-based controller to foster the collaboration between the driver and assist. First, the driver's non-linear steering wheel torque behaviour is modelled and predicted using a Bidirectional Long Short-Term Memory network with an accuracy ≥72.4% and a smoothness ≥0.85Nm/s over a 0.4s prediction horizon. Second, a Model Predictive Controller with a linear bicycle and steering model is developed, where it utilises the driver model's predictions as a time-varying reference. We developed three human-centric controllers for comparison and used a state-of-the-art commercial solution as the baseline controller. The experiments were performed in Toyota Motor Europe's fixed-base driving simulator, where 15 participants tested and evaluated the four controllers. The results show a 113.1% increase in collaborative ratio while maintaining a similar path tracking performance compared to the baseline.
Subject
Haptic shared control
Data-driven driver modelling
Artificial Neural Network
Model Predictive Control
Human-machine interaction
Driving simulator
To reference this document use:
http://resolver.tudelft.nl/uuid:d03311e4-ce03-48a5-88b6-2c784c60c9ce
Embargo date
2025-05-17
Part of collection
Student theses
Document type
master thesis
Rights
© 2023 Hüseyin Harmankaya