Ashly GQX-1502, GQX-3102, GQX-3101 manual Var

7.DESIGN THEORY

While most graphic equalizers look very much the

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same, there are several important differences in the cir- cuitry used to implement various designs.

Perhaps the major differences are in the filters. Some equalizers use a filter made of a capacitor, an in- ductor, and a resistor, or “RLC” filter. The advantage here is simplicity, but the real disadvantage is the induc- tor itself. An inductor is a coil of wire with a core of some sort. Inductors are susceptible to hum fields and they are large and expensive.

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Other equalizers use the same basic approach, but replace the inductor with a “simulated inductor”, which is actually a circuit comprised of an amplifier, a capaci- tor, and a couple of resistors. This adds parts but is less expensive than a real inductor. The problem with this approach is that simulation is less than ideal; it produces an inductor with high resistive loss resulting in poor curve shape when used in a filter.

Another problem with all these “RLC” designs is that large capacitors must be used for the lower frequency filters, limiting the choice to large, expensive non-polar types or electrolytic capacitors with poor audio perfor- mance. Also, when this filter type is combined with a potentiometer to adjust the equalization, the resistance of this pot affects the “Q” of the filter so that a little equal- ization produces a much broader curve than a lot of equal- ization.

Figure 7.1: Passive RLC Filter Design

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Figure 7.2: Simulated Inductor Filter Design

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The other filter approach is a true bandpass filter. This can be made with no inductors and more practical sized capacitors; the “Q” is easily set and remains con- stant, and the parts count is reasonable. there are several types of bandpass filters suitable for this job. Ashly uses

a“Q” enhanced Wein-bridge filter. Because it is a “sym- metrical” design using matched tuning components, the “Q” is easily set and is very stable.

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