Motion Cueing Algorithms (MCAs) render accelerations in a motion-based driving simulator by controlling the motion system of the simulators to provide the driver with a realistic driving experience. However, generating realistic motion is challenging due to the limited workspace of the motion systems of the simulator compared to the motion range of the simulated
vehicle. Commonly used methods such as Classical Washoutbased MCA (CW-MCA) typically achieves suboptimal results due to scaling and filtering, which results in an inefficient usage of the workspace. The Model Predictive Control-based MCA (MPC-MCA) has been shown to achieve superior results and more efficient workspace usage. However, it’s performance is in practice constrained due to the computationally expensive operations and the requirement of an accurate prediction of
future vehicle states. Finally, the Optimal Control (OC) has been
shown to provide optimal cueing in an open-loop setup wherein the precalculated control signals are re-played to the driver. However, OC cannot be used in real-time with the driver-in-theloop. Our work introduces a novel Neural Network-based MCA (NN-MCA), which is trained to imitate the behavior of the OC. After training, the NN-MCA provides an approximated model of the OC, which can run in real-time with the driver in-the-loop, while achieving similar quality. The experiments demonstrate
the potential of this approach through objective evaluations of the generated motion-cues on the simulator model and the real simulator. A high quality video for the performance comparison of the CW-MCA, Optimal-Control-based MCA (OC-MCA) and our proposed method is available at http://bit.ly/2Of8t28.
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Motion Cueing Algorithms (MCAs) render accelerations in a motion-based driving simulator by controlling the motion system of the simulators to provide the driver with a realistic driving experience. However, generating realistic motion is challenging due to the limited workspace of the motion systems of the simulator compared to the motion range of the simulated
vehicle. Commonly used methods such as Classical Washoutbased MCA (CW-MCA) typically achieves suboptimal results due to scaling and fi...
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