Civil Engineering Reference
In-Depth Information
4.8.1.4
Reverberation time
Another effect to be observed in large rooms containing a large quantity of scattering
objects is that the reverberation time is no longer a global quantity, but may vary
systematically with the distance between source and receiver. This effect was observed
by Jovicic (1971) by measurements in large industrial halls and confirmed theoretically
by Vigran (1978) starting out from Jovicic's expressions given above.
The build-up of the scattered energy density in the room is given by Equation
(4.76)
As the build-up and the corresponding decay of sound energy are complimentary
processes we may express the scattered energy density
w
rev
during decay as
t
∫
−
bt
wwWPr t h
=−
(,, )e
⋅
d.
t
(4.81)
rev
s
rc
/
0
Assuming that the mean scattering cross section
q
is relatively large, the scattered energy
will dominate except when near to the source. In such a case we may use this equation
directly to calculate the decay rate and thereby the reverberation time. A comparison
between measured and predicted results is shown in
Table 4.2
. The reverberation time
was measured by Jovicic (1971) in an industrial hall having a floor with dimensions 105
x 105 metres and a ceiling height of 11.5 metres. Measurements were performed in
octave bands in the frequency range 125-4000 Hz at distances between source and
receiver of 20 and 80 metre, respectively. The attenuation coefficient is given as a mean
value,
b
equal to 1.22 m
-1
, for this frequency range, and the mean scattering cross section
q
is stated to be 0.1 m
-1
. The values in the table are average values for this frequency
range and as seen, the fit between measured and predicted values are surprisingly good.
Table 4.2
Measured and predicted values for the mean reverberation time
T
at two different distances between
source and receiver. Mean values for the frequency range 125-4000 Hz, in an industrial hall of volume 125 000
m
3
.
Distance
r
Measured
T
Predicted
T
(m)
(s)
(s)
20
2.65
2.60
80
3.12
3.30
4.8.2
The model of Lindqvist
Lindqvist (1982) developed this analytically based image-source model further by also
taking the reflections from the sidewalls into account, in addition, allowing for a random
positioning of the source and receiver. The shape of the room is, however, still limited to
rectangular, certainly a natural limitation for this kind of model. Based on the work of
Kuttruff (see above), the scattering model applied by Lindqvist is more detailed than the
one used by Jovicic but the scattering objects still have to be stochastically distributed in
the room. The difference in predicted results using these two models will certainly
depend on the actual situation. For relatively large rooms having not too much in the way
of scattering object the differences is assumed to be relatively small, probably in the
range of 1-2 dB.
