There is just too much emphasis on filter ripple, linear phase, and
skirt slope of filters for audio especially voice and CW applications. People
talking of these concerns have read articles, papers or have been involved in
the digital industry. In high speed data communications there is a necessity
of having filters with near perfect linear phase response and ripple. That is
because these systems use a method of sending higher bit rated and bandwidth.
For example a 56K modem transfers 56Kbits per second over a bandwidth of less
than 4KHz. This is done by having several bits represented by a galaxy of
vectors ( phase and amplitude modulation). 3 bits may be transmitted at the
same time by changing the phase and amplitude of the transmitted signal to new
value each time. To transmit 3 bits at a time there are 8 such unique values.
In voice, CW (OOK) and simple modes of digital communications these
concerns are not are unnecessary. The important issues are that you hear the
signals you want to hear and eliminate those you don?t. Also, the issue of
ringing is related to the bandwidth of the filter. Narrower the filter the
longer it will ring. This is due to the fact that a signal can only change just
so fact when passed thru a bandwidth limiting filter.
If you saw what microphones, propagation and speakers did to your voice
and CW signals you would entirely forget the concept of filter perfection
except for the two issues of passing wanted signals and eliminating unwanted
ones.
73
Bill wa4lav done by having several bits represented by a galaxy of vectors (
phase and amplitude modulation). 3 bits may be transmitted at the same time by
changing the phase and amplitude of the transmitted signal to new value each
time. To transmit 3 bits at a time there are 8 such unique values.
In voice, CW (OOK) and simple modes of digital communications these
concerns are not are unnecessary. The important issues are that you hear th
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