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Text File | 1992-10-12 | 5KB | 92 lines

General Purpose ┌─────────────┬───────── + 6 to 18 V High Impedence Preamp │ │ / / \ 220K \ 6.8K / / + │ ├─────┤(────── output │ ┌─C──┘ 10 µF Z Input 10 µF ┌─C──┴────────┤ 2N3094 about 4KΩ Z o──────)├──────┬──────────────B┤ 2N3094 └─E─>┐ 500Ω to + │ └─E─>┐ Q2 │ 3KΩ / Q1 │ │ \ 10K │ │ / 100K │ │ ├─────────/\/\/────────────────────┤ - ───────┐ │ + │ │ │ ─┴─ 10 µF / / R2 │ ─┬─ \ 1K \ 1K │ │ / / └──────┴────────────────────┴─────────────┴───────────── - Referring to the figure above, the circuit can be seen as a direct coupled pair of 2N3094 transistors. This transistor is cheap, high gain, fairly low noise, and very easily obtained. The Q2 transistor is hooked up like any ordinary amplifier stage, but the base resistor that normally goes from its base to ground has been replaced with another transistor, Q1. This Q1 transistor varies the bias on Q2, so the circuit is immune to heat effects. The way it's hooked up, if Q2 draws more current, the voltage on R2 rises, turns on Q1 harder via the 100k resistor connected to its base, and cancels out he inreased current in Q2. The result is almost no change in current due to temperature variations. The capacitor C2 prevents the AC signal from being fed back and reducing the overall gain. By placing the capacitor as shown, a very small value, which is also small in physical size and cheaper, will permit the amplifier to keep ites full gain to low frequencies as well as would be the case for a very large C placed across R2. The values in the figure above will amplify down to about 10 cycles using a physically small capacitor. To make the amplifer roll off at a higher frequency on the low side, reduce C2 to about 1 uF or less, or, alternately you could reduce the 100k resistor to about 10k. This would make the frequency roll off around 100 cycles and turn the circuit into a speech amplifier rather than a hi-fi type. The circuit shown above performs best when driven by a moderate impedance source from 500 ohms to 3k ohms impedance. With this kind of source, the gain will be about 250, and the output noise with no signal in will be about 2 millivolts. This is equivalant to an input noise of only 8 microvolts, so the noise is quite low for all but extraordinary uses. If you wish to drive the circuit with a low impedance source, such as a speaker of 4 to 16 ohms or a telephone earphone (which makes an excellent high output mike), use the circuit in the firgure below. Here, the base is tied to ground via capacitor, and the signal is fed to the emitter of Q1 through a capacitor. This circuit will perform very similarly to the figure above, but will have slightly highly gain reaching perhaps 500 and about the same low noise performance. Ten microfarad capcitors are used thoughout because they are small ad cheap, and are more than enough to do the job here. This simple circuit can be made up in a ball smaller than an acorn and put into mikes to give you more gain than you need to drive even the worst transmitter. It also works well when driven by a speaker put out in the yard to let you listen for prowlers at night, when you don't have to get out of a warm bed, but the dog barks like he's on to something. Fed into any hi-fi input, such a preamp will let you hear better than if you were out in the yard. Here are many other uses, and most of them will please you because the low noise of this preamp lets you really hear clean audio. ┌────────┬────────── + 6 to 18 V General Purpose / / Low Impedence Preamp \ 220K \ 6.8K / Q2 / 10v 10µF Q1 │ ┌─C─┴────────┤(────── Output ┌─C──┴───B┤2N3904 + ┌───────────────B┤2N3904 └─E>┐ │ └─E>┐ │ │ │ 100K │ ├─────────────────── │ ──\/\/──┤ 10 µF │ │ │ Input ─────)├────────────────┐ │ │ Z + +─┴─ C2 │ │ │ 4Ω to 500Ω ─┬─10µF │ / / │ │ \ 1K \ 1K │ │ / / │ │ │ │ - ────────────┴──────────┴─────────┴─────────┴──────────────── -