Dynamic response of the standing human body exposed to vertical vibration: influence of posture and vibration magnitude

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Matsumoto, Y.¹; Griffin, M. J.¹

Dynamic response of the standing human body exposed to vertical vibration: influence of posture and vibration magnitude

J Sound Vibrat. April 23, 1998;212(1):85-107

©1998 Academic Press Limited

Affiliations

¹Human Factors Research Unit, Institute of Sound and Vibration Research, University of Southampton, Southampton, SO17 1BJ, England
Abstract

The influence of the posture of the legs and the vibration magnitude on the dynamic response of the standing human body exposed to vertical whole-body vibration has been investigated. Motions were measured on the body surface at the first and eighth thoracic and fourth lumbar vertebrae (T1, T8 and L4), at the right and left iliac crests and at the knee. Twelve subjects took part in the experiment with three leg postures (normal, legs bent and one leg), and five magnitudes of random vibration (0.125–2.0 ms⁻² r.m.s.) in the frequency range from 0.5–30 Hz. The main resonance frequencies of the apparent masses at 1.0 ms⁻² r.m.s. differed between postures: 5.5 Hz in the normal posture, 2.75 Hz in the legs bent posture and 3.75 Hz in the one leg posture. In the normal posture, the transmissibilities to L4 and the iliac crests showed a similar trend to the apparent mass at low frequencies. With the legs straight, no resonance was observed in the legs at frequencies below 15 Hz. In the legs bent posture, a bending motion of the legs at the knee and a pitching or bending motion of the upper-body appeared to contribute to the resonance of the whole body as observed in the apparent mass, with attenuation of vibration transmission to the upper body at high frequencies. In the one leg posture, coupled rotational motion of the whole upper-body about the hip joint may have contributed to the resonance observed in the apparent mass at low frequencies and the attenuation of vertical vibration transmission at high frequencies. The resonance frequency of the apparent mass in the normal posture decreased from 6.75–5.25 Hz with increasing vibration magnitude from 0.125 to 2.0 ms⁻² r.m.s. This “softening” effect was also found in the transmissibilities to many parts of the body that showed resonances.
Links

DOI: 10.1006/jsvi.1997.1376

WoS: 000073576800006
History

Received: 1997-05-01

Revised: 1997-11-05

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Cited By (28)

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2005	Mansfield NJ. Human Response to Vibration. Boca Raton, FL: CRC Press; 2005.
2013	Zhang Q. Models of a Standing Human Body in Structural Vibration [PhD thesis]. Manchester, UK: University of Manchester; 2013.
2009	Moschioni G, Saggin B, Tarabini M, Zappa E. Comparison between different techniques for the transmissibility measurements. In: 4th International Conference on Whole Body Vibration (WBV2009). June 2-4, 2009; Montreal, QC.49-50.
2013	Wee H, Voloshin A. Transmission of vertical vibration to the human foot and ankle. Ann Biomed Eng. June 2013;41(6):1172-1180.
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.
2014	Tarabini M, Solbiati S, Moschioni G, Saggin B, Scaccabarozzi D. Analysis of non-linear response of the human body to vertical whole-body vibration. Ergonomics. 2014;57(11):1711-1723.
2016	Tarabini M, Solbiati S, Saggin B, Scaccabarozzi D. Apparent mass matrix of standing subjects exposed to multi-axial whole-body vibration. Ergonomics. August 2016;59(8):1038-1049.
2000	Mansfield NJ, Griffin MJ. Non-linearities in apparent mass and transmissibility during exposure to whole-body vertical vibration. J Biomech. August 2000;33(8):933-941.
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.
2002	Matsumoto Y, Griffin MJ. Non-linear characteristics in the dynamic responses of seated subjects exposed to vertical whole-body vibration. J Biomech Eng. October 2002;124(5):527-532.
2008	Kiiski J, Heinonen A, Järvinen TL, Kannus P, Sievänen H. Transmission of vertical whole body vibration to the human body. J Bone Miner Res. August 2008;23(8):1318-1325.
2000	Matsumoto Y, Griffin MJ. Comparison of biodynamic responses in standing and seated human bodies. J Sound Vibrat. December 7, 2000;238(4):691-704.
2002	Matsumoto Y, Griffin MJ. Effect of muscle tension on non-linearities in the apparent masses of seated subjects exposed to vertical whole-body vibration. J Sound Vibrat. May 23, 2002;253(1):77-92.
2002	Mansfield NJ, Griffin MJ. Effects of posture and vibration magnitude on apparent mass and pelvis rotation during exposure to whole-body vertical vibration. J Sound Vibrat. May 23, 2002;253(1):93-107.
2008	Huang Y, Griffin MJ. Nonlinear dual-axis biodynamic response of the semi-supine human body during longitudinal horizontal whole-body vibration. J Sound Vibrat. April 22, 2008;312(1-2):273-295.
2008	Subashi GHMJ, Matsumoto Y, Griffin MJ. Modelling resonances of the standing body exposed to vertical whole-body vibration: effects of posture. J Sound Vibrat. October 2008;317(1-2):400-418.
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.
2010	Hanumanthareddygari V. Neuromotor Response to Whole Body Vibration Transmissibility in the Horizontal Direction and Its Mathematical Model [Master's thesis]. Lawrence, KS: University of Kansas; 2010.
2013	Singh P. Evaluation of Foot-Transmitted Vibration and Transmissibility Characteristics of Mining Boots and Insoles [Master's thesis]. Sudbury, Ontario: Laurentian University; 2013.
2018	Vance B. Establishing a Protocol for the Measurement of Human Exposure to Foot-Transmitted Vibration [Master's thesis]. Sudbury, ON: Laurentian University; 2018.
2012	Wee HB. The Dynamic Model of the Foot and Ankle System [PhD thesis]. Bethlehem, PA: Lehigh University; September 2012.
2015	Solbiati S. Human Body Response to Multi-Axial Dynamical Vibrations [PhD thesis]. Milano, Italy: Politecnico Di Milano; January 2015.
2019	Maugeri S. Modelling the Response of the Human Feet to Vertical Whole-Body Vibration [Master's thesis]. Lecco, Italy: Politecnico Di Milano; 2019.
2006	Boyer KA. Soft Tissue Vibrations and Muscle Tuning During Heel-Toe Running [PhD thesis]. Calgary, AB: University of Calgary; January 2006.
2011	Conrad LF. Whole-Body Vibration on Mobile Machines Within the Steel Making Industry: Assisting Industries With Proper Seat Selection to Retrofit Existing Machines [Master's thesis]. Guelph, ON: University of Guelph; January 2011.
2014	Hu Z. The Development of a Digital X-Ray Imaging System for the Characterization of Transmission of Whole-Body Vibration in Mice [Master's thesis]. London, ON: Western University; 2014.
2007	Christiansen BA. Vibrational Stimulation of Bone Formation in Mice [PhD thesis]. St. Louis, MO: Washington University in St. Louis; December 2007.