4.5 Design of Analogue Filters
|
131
known, they still have to be selected for AnTP(P) according to Equation 4.18 in such
a way that they all lie in the left P- half plane. Furthermore, the constant factor A0
must still be determined that at the passband cut-off frequency ΩD = 1 the magnitude
square of the transfer function |AnTP(Ω= 1)|2 drops to the value
GnTP(jΩ= 1) = |AnTP(jΩ= 1)|2 =
1
1 + ϵ2(Ω= 1)2n =
1
1 + ϵ2
(4.26)
Considering now the pole and zero position representation of the normalised transfer
function AnTP(jΩ) analogous to the representation in Equation 4.18, where here there
are no zeros and the poles after selection all lie in the left P- half plane,
|AnTP(jΩ)| =
A0
1
(jΩ−Pp1) ⋅(jΩ−Pp2) ⋅⋅⋅⋅⋅(jΩ−Ppn)
,
(4.27)
so follows Equation 4.26
|A0| =
AnTP(jΩ= 1) ⋅
n−1
∏
l=0
(j −Ppl)
=
1
√1 + ϵ2
⋅
n−1
∏
l=0
(j −Ppl)
.
(4.28)
Substituting the pole places after Equation 4.25 into Equation 4.28 gives:
A0 = 1
ϵ .
(4.29)
Explanatory Examples
Lowpass 1st order
For filtering an ECG, a passive Butterworth-filter 1st order is to be designed with the
aid of an RC element, which has a passband cut-off frequency of 200 Hz and at this an
attenuation of 3 dB.
For this purpose, the corresponding normalised low-pass filter is first determined.
Since at an attenuation of 3 dB the magnitude square of the frequency response has
the value 0.5, it follows from Equation 4.26 that ϵ = 1 must be. From Equation 4.25 it
follows for the pole positions
P±p0 = ej(π/2±(π+0⋅2π)/2⋅1)
n√1
= ±1
(4.30)
and for |A0|, when all poles are in the left P- half plane, from Equation 4.29:
A0 = 1
ϵ = 1.
(4.31)
So the poles are purely real and are at ±1. The pole in the left P- half plane is therefore
P0 = −1 and is selected. The transfer function of the normalised low-pass can now be
given:
AnTP(P) = A0
1
P −Pp0
=
1
P + 1 .
(4.32)