Civil Engineering Reference
In-Depth Information
Example
In
Figure 4.9
we calculated the difference between the sound pressure and
the power levels for the cases where the absorption area varies between 5 and 200 m
2
.
Correspondingly, the room radius will vary between 0.32 and 1.99 metres.
4.5.2
Measurements of sound pressure levels and reverberation time
As pointed out in the introduction to section
4.5,
the formulae derived using simple
diffuse models are used in a number of measurement tasks both in the laboratory and in
the field. Quantities such as sound pressure squared and reverberation time are
considered, subject to certain presumptions, as global measures but in the sense of being
average values with a space variance. We shall therefore have means to estimate this
variance to be able to predict the uncertainty in the end results, results obtained by
sampling the sound field in the room at a number of microphone positions.
Instead of sampling the sound field in a number of fixed positions, one may use a
microphone moving continuously through the room. As the pressure is strongly
correlated at adjacent positions, positions within some half a wavelength apart, implies
that no new information is gained from close lying positions. The length of the path
covered by such a microphone must therefore be carefully chosen by keeping this in
mind. We shall return to this question later on, first, treating the case of using discrete
sampling of the sound field to determine the average sound pressure squared and the
reverberation time.
One may use several quantities to characterize the measurement uncertainty. It
should also be noted that the expressions for the variance (or standard deviation) may be
given as a relative value or not, which means that they are stated relative to the mean
value or not. The relative variance of an actual quantity
x
shall be defined as
{
}
(
)
2
{}
EE
x
−
x
2
r
()
σ
x
=
,
(4.51)
{}
2
E
x
where the index r indicates a relative value and E{…} the expectation value. The square
root of this expression is denoted the relative, sometimes the normalized, standard
deviation. The symbol
s
is commonly used to indicate the standard deviation, indicating
that practical calculations comprises a limited selection of data enabling us just to
estimate the underlying expectation value.
4.5.2.1
Sound pressure level variance
An early effort to predict the space variance of the squared sound pressure is due to
Lubman (1974), working on the determination of sound power level of sources in a
reverberation room. At frequencies above the Schroeder cut-off frequency
f
S
(see
Equation
(4.22)
) he found a relative variance of 1.0 for pure tone sources assuming that
p
2
was exponentially distributed. The corresponding standard deviation
s
(
L
p
) of the
sound pressure level is then approximately equal to 5.6 dB, which implies that the 95%
confidence interval will be as large as 22 dB. It should not come as a surprise that sound
power level determination of pure tone sources present special problems in order to
arrive at a reasonably correct space averaged value. Sources having a larger bandwidth
will tend to “smear out” these space variations, thereby making the measurement task
considerably easier. We shall present expressions below taking the bandwidth into
account.
