Modelling resonances of the standing body exposed to vertical whole-body vibration:​ effects of posture

Subashi, G. H. M. J.; Matsumoto, Y.; Griffin, M. J.

Affiliations

¹Department of Civil and Environmental Engineering, Saitama University, 255 Shimo-Ohkubo, Sakura, Saitama 338-8570, Japan

²Human Factors Research Unit, Institute of Sound and Vibration Research, University of Southampton, Southampton SO17 1BJ, UK

Abstract

Lumped parameter mathematical models representing anatomical parts of the human body have been developed to represent body motions associated with resonances of the vertical apparent mass and the fore-and-aft cross-axis apparent mass of the human body standing in five different postures: ‘upright’, ‘lordotic’, ‘anterior lean’, ‘knees bent’, and ‘knees more bent’. The inertial and geometric parameters of the models were determined from published anthropometric data. Stiffness and damping parameters were obtained by comparing model responses with experimental data obtained previously.

The principal resonance of the vertical apparent mass, and the first peak in the fore-and-aft cross-axis apparent mass, of the standing body in an upright posture (at 5–6 Hz) corresponded to vertical motion of the viscera in phase with the vertical motion of the entire body due to deformation of the tissues at the soles of the feet, with pitch motion of the pelvis out of phase with pitch motion of the upper body above the pelvis. Upward motion of the body was in phase with the forward pitch motion of the pelvis. Changing the posture of the upper body had minor effects on the mode associated with the principal resonances of the apparent mass and cross-axis apparent mass, but the mode changed significantly with bending of the legs. In legs-bent postures, the principal resonance (at about 3 Hz) was attributed to bending of the legs coupled with pitch motion of the pelvis in phase with pitch motion of the upper body. In this mode, extension of the legs was in phase with the forward pitch motion of the upper body and the upward vertical motion of the viscera.

Links

DOI: 10.1016/j.jsv.2008.03.019

WoS: 000258162400025

History

Received: 2007-09-20

Revised: 2008-02-16

Accepted: 2008-03-10

Online: 2008-05-12

Cited Works (9)

Year	Entry
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Cited By (12)

Year	Entry
2013	Amato F, Bifulco P, Cesarelli M, Colacino D, Cosentino C, Fratini A, Merola A, Romano M. A lumped parameter model for the analysis of the motion of the muscles of the lower limbs under whole-body vibration. In: IEEE 13th International Conference on Bioinformatics and Bioengineering (BIBE). November 10-13, 2013; Chania, Greece.
2021	Moorhead AP, Chadefaux D, Marelli S, Marchetti E, Tarabini M. The effects of vertical whole-body vibration on walking subjects. In: Proceedings of the 8th American Conference on Human Vibration. June 23-25, 2021; Online due to COVID-19.
2021	Chadefaux D, Moorhead AP, Marzaroli P, Marelli S, Marchetti E, Tarabini M. Vibration transmissibility and apparent mass changes from vertical whole-body vibration exposure during stationary and propelled walking. Appl Ergon. January 2021;90:103283.
2013	Tarabini M, Saggin B, Scaccabarozzi D, Gaviraghi D, Moschioni G. Apparent mass distribution at the feet of standing subjects exposed to whole-body vibration. Ergonomics. May 2013;56(5):842-855.
2021	Goggins KA, Chadefaux D, Tarabini M, Arsenault M, Lievers WB, Eger T. Four degree-of-freedom lumped parameter model of the foot-ankle system exposed to vertical vibration from 10 to 60 Hz with varying centre of pressure conditions. Ergonomics. 2021;64(8):1002-1017.
2019	Nawayseh N, Hamdan S. Apparent mass of the standing human body when using a whole-body vibration training machine: effect of knee angle and input frequency. J Biomech. January 3, 2019;82:291-298.
2020	Chadefaux D, Goggins K, Cazzaniga C, Marzaroli P, Marelli S, Katz R, Eger T, Tarabini M. Development of a two-dimensional dynamic model of the foot-ankle system exposed to vibration. J Biomech. January 23, 2020;99:109547.
2014	Książek MA, Tarnowski J. Experimental studies of the influence of human standing positions on the feet-to-head transmission of vibrations. J Theo Appl Mech. 2014;52(4):1107-1114.
2019	Marzaroli P, Albanetti A, Negri E, Giberti H, Tarabini M. Design and testing of a 3-DOF robot for studying the human response to vibration. Machines. December 2019;7(4):67.
2019	Goggins KA. Measuring and Modelling Human Response to Foot-Transmitted Vibration Exposure [PhD thesis]. Sudbury, ON: Laurentian University; 2019.
2015	Solbiati S. Human Body Response to Multi-Axial Dynamical Vibrations [PhD thesis]. Milano, Italy: Politecnico Di Milano; January 2015.
2019	Marzaroli P. Development of Tools and Systems for the Protection of Workers from Foot-Transmitted Whole-Body Vibration [PhD thesis]. Politecnico di Milano; 2019.