Consoles 891around today’s more familiar op-amp technology rather
than discrete transistors or tubes. Fig. 25-67A shows a
virtual-earth-type inverting amplifier with the gain
(being equal to the ratio of the feedback resistor RF to
the series resistor RS) continuously variable from
near-infinite loss (min) to near-infinite gain (max) with
unity in the middle. If a fixed-gain-determining leg is
introduced and the variable leg is made frequency
conscious, as shown in Fig. 25-67B (in this instance by
crude single-order high-pass filters—the series capaci-
tors), the gain swing only occurs within the passband of
those filters. The through gain for the rest of the spec-
trum is determined by the two fixed resistors. If this
fixed chain is replaced by a second frequency-conscious
network that does not significantly overlap the original
one in bandwidth, the two chains independently modify
their frequency areas, Fig. 25-67C. The fixed chain is
only necessary where the gain is otherwise unpredict-
ably defined by a frequency-conscious network.
The belt-and-braces low-pass arrangement (for
low-frequency boost and cut) of Fig. 25-67C can be
rationalized into the more elegant circuit of Fig.
25-67D. This circuit more closely resembles the defini-
tive Baxandall circuit. Rather than isolating the
low-frequency boost-and-cut chain with increasing
inductive reactance, the control is buffered away with
relatively small resistances and bypassed to high
frequencies by capacitance. The control takes progres-
sively greater effect at lower frequencies as the rising
capacitative reactance reduces the effective bypass. A
further refinement is a pair of stopper resistors, small in
value, that define the maximum boost and cut of the
entire network.
Naturally, a more complex EQ can be configured
around the same arrangement. A midfrequency bell
curve is easily introduced by any of the means in Fig.
25-68, giving a good hint on how to avoid using a real
tuned circuit using inductors.
A variable signal either positive or negative in phase
to the source Vin can be picked off from a pot straight
across the existing high-frequency and low-frequency
chains, taken to an active filter arrangement to derive
the needed amplitude response shape. The signal is then
returned to the loop at either the virtual-earth point (to
which the high-frequency and low-frequency chains are
tied) or to the noninverting reference input, Fig.
25-68D, depending on whether the absolute phase of the
filter is positive or negative. Industry favorites seem to
be this approach using either a Wein Bridge bandpass or
a state-variable integrator-loop type.
Any number of such active chains may be introduced,
provided two great hangups don’t intrude excessively:
Figure 25-68. Resonant frequency selective elements in the
Baxandall equalizer.C. Single series tuned bypass filter.B. Single parallel tuned element.Bypass
techniqueVin VoMFVin VoSeries techniqueThese resistors
can also signify
existing HF/LF chainsMFVin VoA. Series tuned symmetrical bandpass.D. Using an active filter element.Vin Vo
Response
shaping
active
filter
(inverting)