FM Deemphasis: Difference between revisions

An analog deemphasis filter:

              R
   o------/\/\/\/---+----o
                  |
                 = C
                  |
                 ---

Has this transfer function:

              1             1
             ----          ---
              RC          tau
   H(s) = ---------- = ----------
                1             1
           s + ----      s + ---
                RC           tau

And has its -3 dB response, due to the pole, at

   |H(j w_c)|^2 = 1/2  =>  s = j w_c = j (1/(RC))

Historically, this corner frequency of analog audio deemphasis filters been specified by the RC time constant used, called tau. So w_c = 1/tau.

FWIW, for standard tau values, some standard analog components would be:

   tau = 75 us = (50K)(1.5 nF) = (50 ohms)(1.5 uF)
   tau = 50 us = (50K)(1.0 nF) = (50 ohms)(1.0 uF)

In specifying tau for this digital deemphasis filter, tau specifies the *digital* corner frequency, w_c, desired.

The digital deemphasis filter design below, uses the "bilinear transformation" method of designing digital filters:

1. Convert digital specifications into the analog domain, by prewarping digital frequency specifications into analog frequencies.

w_a = (2/T)tan(wT/2)

2. Use an analog filter design technique to design the filter.

3. Use the bilinear transformation to convert the analog filter design to a digital filter design.

H(z) = H(s)|
                s = (2/T)(1-z^-1)/(1+z^-1)

        w_ca         1          1 - (-1) z^-1
   H(z) = ---- * ----------- * -----------------------
        2 fs        -w_ca             -w_ca
                1 - -----         1 + -----
                     2 fs              2 fs
                              1 - ----------- z^-1
                                      -w_ca
                                  1 - -----
                                       2 fs

We use this design technique, because it is an easy way to obtain a filter design with the -6 dB/octave roll-off required of the deemphasis filter.

Jackson, Leland B., _Digital_Filters_and_Signal_Processing_Second_Edition_, Kluwer Academic Publishers, 1989, pp 201-212

Orfanidis, Sophocles J., _Introduction_to_Signal_Processing_, Prentice Hall, 1996, pp 573-583

Parameters

Sample Rate

Sampling frequency in Hz

Tau

Time constant in seconds (75us in US, 50us in EUR)

Example Flowgraph

This flowgraph implements a Broadcast FM stereo receiver using basic blocks.

Source Files

Python files

[1]

Block definition

[2]