Driving-point mechanical impedance of the human hand-arm system: synthesis and model development

wbldb

Gurram, R.¹; Rakheja, S.¹; Brammer, A. J.²

Driving-point mechanical impedance of the human hand-arm system: synthesis and model development

J Sound Vibrat. February 23, 1995;180(3):439-458

©1995 Academic Press Limited

Affiliations

¹CONCAVE Research Centre, Department of Mechanical Engineering, Concordia University, Montreal, Quebec, Canada, H3G 1M8

²Institute for Micro-Structural Sciences, National Research Council of Canada, Ottawa, Ontario, Canada, K1A 0R6
Abstract

A synthesis of the measured values of human male hand-arm impedance characteristics reported in the literature has been performed. The driving-point mechanical impedance data of the human hand-arm grasping a vibrating handle has been compared to highlight the various similarities and differences among the data. Unexplained differences among the results of various studies, conducted independently under nominally equivalent measurement conditions, led to the exclusion of outliers from the analysis. The most probable values of impedance phase and magnitude are defined by lower and upper envelopes of the mean values of the accepted data sets. The mean of the data sets, together with the smoothened envelopes, are used to define the target and range of idealized values of the X_h, Y_h and Z_h components of impedance in the 10–1000 Hz frequency range. A pooling of results from different studies suggests that there is a small dependence of the X_h component of impedance magnitude on the hand grip forces. The dependence of the phase of the corresponding impedance component on the hand grip force, however, is insignificant. There is insufficient data from independent sources to establish a dependence of other components of impedance on the hand grip and thrust forces. A four-degrees-of-freedom, lumped parameter model is derived to fit the target impedance magnitude and phase values using a constrained optimization algorithm. The predicted values correlate well with the target values in the selected frequency range.
Links

DOI: 10.1006/jsvi.1995.0089

WoS: A1995QJ46800005
History

Received: 1993-03-23

Accepted: 1993-11-15

Cited Works (9)

Year	Entry
1982	Griffin MJ, Macfarlane CR, Norman CD. The transmission of vibration to the hand and the influence of gloves. In: Brammer A., Taylor W, eds. Vibration Effects on the Hand and Arm in Industry. New York, NY: John Wiley & Sons; 1982:103-116.
1990	Griffin MJ. Handbook of Human Vibration. London, UK: Academic Press Limited; 1990.
1986	Mechanical Vibration: Guidelines for the Measurement and the Assessment of Human Exposure to Hand-Transmitted Vibration. ISO Standard ISO 5349. [ISO Standard thesis]. Geneva, Switzerland: International Organization for Standardization; 1986.
1986	Jahn R, Hesse M. Applications of hand-arm models in the investigation of the interaction between man and machine. Scand J Work Environ Health. August 1986;12(4):343-346.
1987	Brammer AJ, Taylor W, Lundborg G. Sensorineural stages of the hand-arm vibration syndrome. Scand J Work Environ Health. August 1987;13(4):279-283.
1993	Gurram R. A Study of Vibration Response Characteristics of the Human Hand-Arm System [PhD thesis]. Montreal, QC: Concordia Universit; September 1993.
1979	Miwa T, Yonekawa Y, Nara A, Kanada K, Baba K. Vibration isolators for portable vibrating tools, I: a grinder. Ind Health. 1979;17(2):85-101.
1984	Reynolds DD, Falkenberg RJ. A study of hand vibration on chipping and grinding operators, II: four-degree-of-freedom lumped parameter model of the vibration response of the human hand. J Sound Vibrat. August 22, 1984;95(4):499-514.
1987	Gemne G, Pyykkö I, Taylor W, Pelmear PL. The Stockholm Workshop scale for the classification of cold-induced Raynaud's phenomenon in the hand-arm vibration syndrome (revision of the Taylor-Pelmear scale). Scand J Work Environ Health. 1987;13(4):275-278.

Cited By (20)

Year	Entry
2003	Dong RG, Rakheja S, Smutz WP, Schopper AW, Caporali SA. Dynamic characterization of instrumented handle and palm-adapter used for assessment of vibration transmissibility of gloves. J Test Eval. May 2003;31(3):234-246.
2015	Dong RG, Sinsel EW, Welcome DE, Warren C, Xu XS, McDowell TW, Wu JZ. Review and evaluation of hand–arm coordinate systems for measuring vibration exposure, biodynamic responses, and hand forces. Saf Health Work. September 2015;6(3):159-173.
2004	Dong RG, Warren C, Welcome DE, McDowell TW, Wu JZ. A comparison and evaluation of reported mechanical impedance data of the human hand-arm system. In: Proceedings of the 10th International Conference on Hand-Arm Vibration. June 7-11, 2004; Las Vegas, NV.221-227.
2004	Haasnoot RA, Mansfield NJ. Effect of push/pull and grip force on perception of steering wheel vibration. In: Proceedings of the 10th International Conference on Hand-Arm Vibration. June 7-11, 2004; Las Vegas, NV.287-293.
2004	Marcotte P, Aldien Y, Boileau P-É, Rakheja S, Boutin J. Influence of handle size and shape on the biodynamic response of the hand-arm system. In: Proceedings of the 10th International Conference on Hand-Arm Vibration. June 7-11, 2004; Las Vegas, NV.231-232.
2004	Moustafa AK, Reynolds D. Mecahnical impedance characteristics of the hand and arm. In: Proceedings of the 10th International Conference on Hand-Arm Vibration. June 7-11, 2004; Las Vegas, NV.229-230.
2001	Dong RG, Rakheja S, Schopper AW, Han B, Smutz WP. Hand-transmitted vibration and biodynamic response of the human hand-arm: a critical review. Crit Rev Biomed Eng. 2001;29(4):393-439.
2005	Dong RG, Wu JZ, Welcome DE. Recent advances in biodynamics of human hand-arm system. Ind Health. July 2005;43(3):449-471.
2017	Xu XS, Dong RG, Welcome DE, Warren C, McDowell TW, Wu JZ. Vibrations transmitted from human hands to upper arm, shoulder, back, neck, and head. Int J Ind Ergon. November 2017;62:1-12.
2007	Dong RG, Dong JH, Wu JZ, Rakheja S. Modeling of biodynamic responses distributed at the fingers and the palm of the human hand–arm system. J Biomech. 2007;40(10):2335-2340.
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.
2004	Dong RG, Welcome DE, McDowell TW, Wu JZ. Biodynamic response of human fingers in a power grip subjected to a random vibration. J Biomech Eng. August 2004;126(4):447-457.
2002	Rakheja S, Wu JZ, Dong RG, Schopper AW, Boileau P-É. A comparison of biodynamic models of the human hand–arm system for applications to hand-held power tools. J Sound Vibrat. January 3, 2002;249(1):55-82.
2005	Marcotte P, Aldien Y, Boileau P-É, Rakheja S, Boutin J. Effect of handle size and hand–handle contact force on the biodynamic response of the hand–arm system under z_h-axis vibration. J Sound Vibrat. May 20, 2005;283(3-5):1071-1091.
2006	Dong RG, Welcome D., McDowell TW, Wu JZ. Measurement of biodynamic response of human hand–arm system. J Sound Vibrat. July 2006;294(3):807-827.
2009	Concettoni E, Griffin M. The apparent mass and mechanical impedance of the hand and the transmission of vibration to the fingers, hand, and arm. J Sound Vibrat. August 21, 2009;325(3):664-678.
2010	Adewusi SA, Rakheja S, Marcotte P, Boutin J. Vibration transmissibility characteristics of the human hand–arm system under different postures, hand forces and excitation levels. J Sound Vibrat. July 5, 2010;329(14):2953-2971.
2013	Dong RG, Welcome DE, McDowell TW, Wu JZ. Modeling of the biodynamic responses distributed at the fingers and palm of the hand in three orthogonal directions. J Sound Vibrat. February 2013;332(4):1125-1140.
2015	Xu XS, Dong RG, Welcome DE, Warren C, McDowell TW. An examination of an adapter method for measuring the vibration transmitted to the human arms. Measurement. September 2015;73:318-334.
2019	Goggins KA. Measuring and Modelling Human Response to Foot-Transmitted Vibration Exposure [PhD thesis]. Sudbury, ON: Laurentian University; 2019.