Civil Engineering Reference
In-Depth Information
Another procedure is by way of analytical modelling using transfer matrices.
Basically, each layer in the combination, assumed to be of infinite extent, is represented
by a matrix giving the relationship between a set of physical variables on the input and
output side of the layer. These matrices may then be combined to give the relationship
between the relevant physical variables for the whole combination. Characteristic data as
absorption factor, input impedance and sound reduction index (transmission loss) may
then be calculated assuming plane wave incidence. The size and complexity of these
matrices, however, are totally dependent on the specific material in the actual layer, i.e.
how many physical variables one has to use describing the wave motion in the material
and then how many material parameters that are necessary to specify the material. In
many cases, two physical variables are sufficient i.e. the sound pressure and the particle
velocity. A simple 2 by 2 matrix then describes the relationship between these variables
on the input and the output side. We shall use this description below to illustrate the
method.
5.7.1
Modelling by transfer matrices
For the description of layers e.g. thin plates (panels), either perforated or non-perforated,
two physical variables are always sufficient. The word “thin” here signify that we do not
need to worry about the wave motion inside the plate itself; the wavelength being much
longer than the thickness of the plate. With thicker elastic materials this simple model is
no longer feasible (see the discussion below).
Porous materials may also be included in a simple 2 by 2 matrix description if they
are modelled as an equivalent fluid. Such a model is applicable to many porous materials,
e.g. mineral wool type absorbers. The basic assumptions are that the material is
homogeneous and isotropic, having pores filled with air embedded in an infinitely stiff
matrix or skeleton. Again, if the elastic properties of this skeleton have to be taken into
account a description using two physical variables only is not feasible.
In our outline of the transfer matrix method we shall only use the 2 by 2 matrices,
which in the analogue electrical case is denoted a two port or four pole. Using the sound
pressure
p
together with particle velocity
v
as the variables, we can express the
relationship between these variables on each side of the layer numbered n:
p
a
a
p
⎡
⎤ ⎡
⎤⎡ ⎤
n 1
−
11
12
n
=
.
(5.75)
⎢
⎥ ⎢
⎥⎢ ⎥
v
a
a
v
⎣
⎦ ⎣
⎦⎣ ⎦
n 1
−
21
22
n
The matrix for the total system, i.e. the one describing the relation between variables on
the input and output side of the system, is arrived at by multiplying together the matrices
representing each of the contributing layers. Denoting the elements in this matrix as
A
11
,
A
12
,
A
21
and
A
22
, the input impedance
Z
g
is given by
p
A ZA
+
0
11
L
12
Z
==
,
(5.76)
g
v
AZA
+
0
21
L
22
where
Z
L
is the impedance on the output side, the load impedance. As shown earlier,
when
Z
g
is known we are able to calculate the absorption factor by using the expressions
