Although many studies exist concerning the influence of seat vibration on the head in the seated human body, the dynamic response of the head-neck complex (HNC) to the trunk vibration has not been well investigated. Little quantitative knowledge exists about viscoelastic parameters of the neck. In this study, the dynamics of the HNC is identified when it is exposed to the trunk horizontal (fore-and-aft) vibration. The frequency response functions between the HNC angular velocity and the trunk horizontal acceleration, corresponding to four volunteers, are obtained in the frequency range of 0.5 Hz to 10 Hz. A fourth-order mathematical model, derived by considering a double-inverted-pendulum model for the HNC, is designed to simulate the dynamic response of the HNC to the trunk horizontal vibration. The frequency domain identification method is used to determine the coefficients of the mathematical model of the HNC. Good agreement has been obtained between experimental and simulation results. This indicates that the system, similar to the designed fourth-order model, has mainly two resonance frequencies. The viscoelastic parameters of the neck, including the spring and damping coefficients, are then obtained by use of the optimization method.

Issue Section:
Joint/Whole Body
Keywords:
biomechanics, vibrations, dynamic response, angular velocity, physiological models, frequency-domain analysis, viscoelasticity, damping, parameter estimation, Head-Neck Complex, Modeling, Double Inverted Pendulum, Frequency Domain Identification, Spring and Damping Coefficients
Topics:
Damping, Dynamics (Mechanics), Modeling, Pendulums, Springs, Transfer functions, Vibration, Dynamic response, Frequency response, Resonance
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