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New human body models have been developed with recent anthropometry for riding comfort simulation. External geometry of the models was acquired from the three dimensional whole body laser scanning of recruited volunteers in a driving position. The selection criteria for volunteers with standard size and shape were derived from a statistical factor analysis of the SizeUSA database. As a practical application of the model in a design process, comfortable driving postures were constructed by using the Cascade Prediction Model (CPM) which takes into account both interior package layout and the driver's anthropometry.

In order to improve the biofidelity of a finite element human body model, previously introduced as PAM-Comfort model, the modeling of lumbar spine, buttock and trunk back flesh and abdominal part have been updated. The modeling of the lumbar spine has been improved for its mechanical characteristics of articulation. The modeling of abdominal part has been switched with solid mesh from the air-bag with membrane elements to enhance the mass distribution feature of the model. The mesh quality of buttock and trunk back flesh became finer for a more accurate prediction of seating pressure distribution. The new features of the model were verified by the experimental data with human subjects.

Riding comfort on the seat is one of the important factors for vehicle comfort. To analyze riding comfort, there were some models for predicting human vibrations in the past studies. On the other hand, it is strongly affected by human body motion caused by vehicle excitation during driving especially low frequency, but it is difficult to predict human motion due to an unclear mechanism of muscle reflex. The purpose of this study is to construct virtual riding comfort testing simulation based on virtual prototyping of the seat. In this study, a virtual occupant model that predicts occupant motion on the seat against external excitation including muscle reflex for maintaining sitting posture constructed. The whole body was modeled as 15 segments biomechanical model (1D) with wobbling mass. Each joint has passive elastic torque and damping torque springs. Human body surface was modeled as rigid shape.

Discomfort models play a significant role in ergonomic simulation. More detailed and specific discomfort models are required for older drivers who represent the fastest-growing segment of the driving population. Owing to the physical degradation, various biomechanical discomfort factors should be incorporated into the model to properly evaluate discomfort for the older population group. In this experimental study we attempted to identify and quantify biomechanical factors that affect the older drivers' discomfort ratings. Different egress motion strategies (e.g., with and without using assist devices) were designed to induce various physical activities. The corresponding discomfort ratings were then produced. From the kinematic analysis using a digital human body model with reconstructed egress motion, the hip abduction was found to have the most statistically significant effect on the discomfort rating.