Effects of frequency, magnitude, damping, and direction on the discomfort of vertical whole-body mechanical shocks

Although much research has been devoted to the determination of equivalent comfort contours for human response to whole-body vibration little consideration has been given to the source of the feelings that give rise to such comfort contours. This paper shows that for vertical vibration there is a di

The power absorbed by 12 male subjects during exposure to vertical whole-body vibration at six magnitudes of random vibration (0•25, 0•5, 1•0, 1•5, 2•0 and 2•5 ms -2 r.m.s.) has been measured in the laboratory. All subjects showed greatest absorbed power at about 5 Hz, but the frequency of this peak

The interaction between the frequency of vibration and the relative phase between vibration at the seat and the feet on the discomfort of seated subjects exposed to vertical vibration has been investigated in an experimental study. Twelve seated subjects were exposed to sinusoidal vibration at "ve f

The e!ect of variations in posture and vibration magnitude on apparent mass and seat-to-pelvis pitch transmissibility have been studied with vertical random vibration over the frequency range 1)0}20 Hz. Each of 12 subjects was exposed to 27 combinations of three vibration magnitudes (0)2, 1)0 and 2)

Methods of predicting the discomfort caused by rotational vibration of subjects seated away from the axis of rotation from a knowledge of the discomfort caused by single-axis vibration were investigated. The method of category production was used, in which ten seated subjects adjusted the level of s