144

|

4 Measurement of Biosignals and Analog Signal Processing

Bn(P) :=

n

∑

i=0

(2n −i)!Pⁱ

2ⁿ⁻ⁱi!(n −i)! ^,

i = 0, 1, . . . , n .

(4.89)

Examples are:

B1(P) = 1 + P

B2(P) = 3 + 3P + P²

B3(P) = 15 + 15P + 6P² + P³

B4(P) = 105 + 105P + 45P² + 10P³ + P⁴

B5(P) = 945 + 945P + 420P² + 105P³ + 15P⁴ + P⁵ .

Explanatory Example

For ECG filtering, design a passive Bessel filter of 2nd order using an RLC element

which has a passband cut-off frequency of 200 Hz and at this an attenuation of 3 dB.

In this case the Bessel polynomial of 2nd order is B2(P) = 3 + 3P + P². The delay

time T is chosen such that at the normalised passband cut-off frequency ΩD = 1 the

attenuation of 3 dB can be maintained, i.e.

|AnTP(P = jΩD)| = |AnTP(P = j)| =

3

󵄨󵄨󵄨󵄨3 + j3T + (jT)2󵄨󵄨󵄨󵄨

= ¹

√2

.

(4.90)

One thereby obtains T = 1.3823 s. If we now denormalise so that the passband cut-off

frequency is fD = 200 Hz and compare this with the transfer function ARLC(jω) of an

RLC element one obtains because of

A(jω)Bessel = AnTP (P = j ^ω

ωD

) =

3

3 + 3j ^ω

ωD ^{T + (j ω}

ωD ^T)

2

= ARLC(jω) =

1

1 + jωRC + (jω)²LC

(4.91)

the relation:

RC = T/ωD

und

LC = ¹

3 ^{(T/ωD)2 .}

(4.92)

Choosing R = 100 Ω, it follows with the forward frequency fD = 200 Hz and T =

1.3823 s for the inductance L = 36.7 mH and for the capacitance C = 11 μF. The

phase response in the passband is linear (cf. Figure 4.48).

4.6 Post-Reading and Exercises

Measurement of Electrical Biosignals

1.

Why is analog signal processing needed in the digital age?

2.

What would be the skin impedance for a infinitely high frequency current?