Journal of the Korean Society for Precision Engineering

"인체 모델"

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Air- and Bone-conduction Effects in Vehicle Interior Noise and Vibration Evaluation: A 12-DOF Human Model-head Finite Element Study: Jongyeon Yoon, Daeun Jeong, Namkeun Kim; J. Korean Soc. Precis. Eng. 2025;42(9):713-721.
Published online September 1, 2025; DOI: https://doi.org/10.7736/JKSPE.025.085

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The rise of electric vehicles (EVs) has led to a reduction in engine noise, making suspension and road noise more noticeable. However, most assessments focus only on air-conducted (AC) pathways and overlook bone-conducted (BC) transmission. This study identifies key sources of vehicle noise and implements a finite-element simulation to replicate real-world driving conditions. A 12-degree-of-freedom (DOF) human body model quantifies how vibrations transmit from the vehicle structure to the head. Additionally, a detailed finite-element model of the human head evaluates basilar-membrane (BM) vibrations for both AC and BC inputs. The results indicate that BC dominates below 10 Hz, producing BM velocities up to 50 dB greater than AC. Above 10 Hz, AC prevails, showing a difference of approximately 40 dB. Notably, at frequencies of 33, 46, 67, and 80 Hz, the AC–BC difference narrows to below 10 dB, highlighting significant BC effects even at higher frequencies. These findings reveal that neglecting bone-conduction pathways can lead to an underestimation of occupant exposure to low-frequency vibrations. Therefore, comprehensive evaluations and control methods for vehicle noise should consider both AC and BC transmission mechanisms to accurately reflect human perception

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Driver Behavior Simulation considering Crash Condition of an Automated Vehicle: Moon Young Kim, Jangu Lee, Jayil Jeong; J. Korean Soc. Precis. Eng. 2022;39(3):187-192.
Published online March 1, 2022; DOI: https://doi.org/10.7736/JKSPE.021.122

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In this study, the behavior of the driver was derived by conducting a crash simulation considering automated vehicle accident conditions using autonomous emergency braking (AEB) and a human body model (HBM). Based on car-to-car intersection accident conditions in the OSCCAR project and the actual accident report, a crash accident case was selected. The base crash scenario was reconstructed by conducting a driving simulation with reference to the selected accident cases. Additional simulations applying AEB are performed. Based on the boundary conditions, a car-to-car crash simulation was performed to derive a crash pulse. This crash pulse and HBM were applied to a simple cabin model for conducting driver behavior analysis. The results confirmed that the head behavior of the driver of the opposing vehicle increased in the lateral direction.

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Vehicle-motion-based Front Wheel Steer Angle Estimation for Steer-by-Wire System Fault Tolerance
Seungyong Choi, Wanki Cho, Seung-Han You
Journal of the Korean Society for Precision Engineering.2024; 41(5): 347. CrossRef