Effect of muscle tension on non-linearities in the apparent masses of seated subjects exposed to vertical whole-body vibration

Matsumoto, Y.; Griffin, M. J.

Affiliations

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

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

Abstract

In subjects exposed to whole-body vibration, the cause of non-linear dynamic characteristics with changes in vibration magnitude is not understood. The effect of muscle tension on the non-linearity in apparent mass has been investigated in this study. Eight seated male subjects were exposed to random and sinusoidal vertical vibration at five magnitudes (0.35–1.4 m/s² r.m.s.). The random vibration was presented for 60 s over the frequency range 2.0–20 Hz; the sinusoidal vibration was presented for 10 s at five frequencies (3.15, 4.0, 5.0, 6.3 and 8.0 Hz). Three sitting conditions were adopted such that, in two conditions, muscle tension in the buttocks and the abdomen was controlled. It was assumed that, in these two conditions, involuntary changes in muscle tension would be minimized. The force and acceleration at the seat surface were used to obtain apparent masses of subjects. With both sinusoidal and random vibration, there was statistical support for the hypothesis that non-linear characteristics were less clear when muscle tension in the buttocks and the abdomen was controlled. With increases in the magnitude of random vibration from 0.35 to 1.4 m/s² r.m.s., the apparent mass resonance frequency decreased from 5.25 to 4.25 Hz with normal muscle tension, from 5.0 to 4.38 Hz with the buttocks muscles tensed, and from 5.13 to 4.5 Hz with the abdominal muscles tensed. Involuntary changes in muscle tension during whole-body vibration may be partly responsible for non-linear biodynamic responses.

Links

DOI: 10.1006/jsvi.2001.4250

WoS: 000176286500007

History

Accepted: 2001-10-19

Cited Works (11)

Year	Entry
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1997	Mechanical Vibration and Shock: Evaluation of Human Exposure to Whole-Body Vibration, I: General Requirements. ISO Standard ISO 2631-1. [ISO Standard thesis]. Geneva, Switzerland: International Organization for Standardization; 1997.
1989	Seroussi RE, Wilder DG, Pope MH. Trunk muscle electromyography and whole body vibration. J Biomech. 1989;22(3):219-229.
1998	Matsumoto Y, Griffin M. Movement of the upper-body of seated subjects exposed to vertical whole-body vibration at the principal resonance frequency. J Sound Vibrat. August 27, 1998;215(4):743-762.
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.
1997	Kitazaki S, Griffin MJ. A modal analysis of whole-body vertical vibration, using a finite element model of the human body. J Sound Vibrat. February 13, 1997;200(1):83-103.
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.
2001	Matsumoto Y, Griffin MJ. Modelling the dynamic mechanisms associated with the principal resonance of the seated human body. Clin Biomech (Bristol, Avon). 2001;16(suppl 1):S31-S44.
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.

Cited By (13)

Year	Entry
2005	Mansfield NJ. Human Response to Vibration. Boca Raton, FL: CRC Press; 2005.
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	Zhou Z, Griffin MJ. Response of the seated human body to whole-body vertical vibration: biodynamic responses to sinusoidal and random vibration. Ergonomics. May 2014;57(5):693-713.
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.
2006	Dickey JP, Oliver ML, Boileau P-E, Eger TR, Trick LM, Edwards AM. Multi-axis sinusoidal whole-body vibrations, I: how long should the vibration and rest exposures be for reliable discomfort measures? J Low Freq Noise Vib Act Control. 2006;25(3):175-184.
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.
2005	Nawayseh N, Griffin MJ. Non-linear dual-axis biodynamic response to fore-and-aft whole-body vibration. J Sound Vibrat. April 22, 2005;282(3-5):831-862.
2006	Morioka M, Griffin MJ. Magnitude-dependence of equivalent comfort contours for fore-and-aft, lateral and vertical whole-body vibration. J Sound Vibrat. December 12, 2006;298(3):755-772.
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.
2013	Singh P. Evaluation of Foot-Transmitted Vibration and Transmissibility Characteristics of Mining Boots and Insoles [Master's thesis]. Sudbury, Ontario: Laurentian University; 2013.
2002	Giacomin JA. An Experimental Investigation of the Vibrational Comfort of Child Safety Seats [PhD thesis]. University of Sheffield; December 2002.
2012	Jack RJ. Investigating Whole-Body Vibration Injuries in Forestry Skidder Operators: Combining Operator Vibration Exposures and Postures in the Field With Biodynamic Responses in the Laboratory [PhD thesis]. Guelph, ON: University of Guelph; January 2012.