On The Bench: Amplifier Design

Text: Rob Squire

CLASS-B

Class-B amplifiers require two active devices to operate, with each device amplifying only one half of the input signal. With no input signal present the bias applied to both devices is such that they’re just turned off and thus consume no current from the power supply. When an input signal is applied, the first device will switch on and conduct on only the positive waveform excursions, while the other device remains off. On negative excursions the first device will turn off and the other will begin to conduct. Keeping the devices just turned off, hovering ready for one or the other to conduct when the smallest input signal appears is exceedingly difficult to set up, and in the real world, essentially impossible. This gives rise to crossover distortion, a kind of dead zone where every time the signal swings from positive to negative both devices are off, the output is no longer following the input signal and gross distortion occurs. The upside of this amplifier design is that Class-B amplifiers are pretty efficient at converting power from the power supply to the signal output.

CLASS-AB

Class-AB amplifiers are a marriage of the efficiency of Class-B with the crossover distortion-free benefits of Class-A. Here the amplifier is biased such that both output devices are just barely turned on, as opposed to just turned off. Operating as a Class-A amplifier for small signals, these output devices are conducting all the time and neither device is turned fully off. As the signal level gets larger, the amplifier will reach a point where one device will turn off and the amplifier now operates in Class-B mode. Since this transition happens at a higher signal level the crossover distortion (as a percentage of the signal) will be much lower. Class-AB can be operated or ‘biased on’ to various degrees, increasing the range of signal levels at which the amplifier remains operating in Class-A. These are sometimes referred to as AB1 or AB2 etc. The vast majority of amplifiers are Class-AB: most hi-fi stereo amps, all integrated circuit op-amps, self-powered monitor speakers, the output section of tube guitar amps, etc. Despite still suffering to some extent from crossover distortion we’ll soon see how that can be further minimised.

CLASS-C

In the pursuit of efficiency, Class-C amplifiers are biased such that they only conduct for 50% or less of the input signal. In essence, half or more of the input signal just isn’t reproduced at all. This equates to severe distortion and is well and truly into total fuzz territory and therefore pretty useless for audio purposes. For AM radio transmitters, however, it’s just the ticket – the 90% efficiency is handy when you’re pumping out 10,000W! Since AM radio transmitters are amplifying just one single frequency, a highly tuned, high-Q filter can be placed on the amplifier’s output, effectively removing all the distortion products and restoring the waveform to its original pure single frequency.

CLASS-D

‘D’ doesn’t stand for ‘digital’ – let’s get that out of the way first up. Most Class-D amplifiers convert the audio to a stream of very high-frequency pulses where the pulse width is representative of the original audio waveform. This is known as pulse width modulation. The output amplifier device in this situation simply has to turn fully on or fully off in response to each pulse, resulting in very high efficiency. Mosfets are the device of choice for Class-D amplifiers as they can have very low resistance, resulting in very low heat dissipation when turned on hard and thus minimal power is wasted as heat. The switching or pulse frequency must be at least twice that of the highest audio frequency you wish to reproduce. In practice, Class-D amplifiers often run at 10 times the highest audio frequency of interest – namely, 20kHz. Mosfets are also well suited to this very high speed of operation. Class-D is one of the increasingly popular choices for today’s extraordinarily high-powered PA amps and goes some way to explaining how you can get an 8000W amplifier into a two-unit rack case without the unit melting its way through to the centre of the earth. The MC² E90 power amp reviewed in Issue 70 is an example of a massive Class-D amplifier, achieving 84% efficiency in converting the incoming mains 230Vac to 16,000W of audio power. All Class-D amplifiers require extensive passive filtering on their outputs to remove the high-frequency information from the width modulated pulses and effectively reconstitute the original audio waveform.

CLASS-G & H

Lets jump right past Class-E and F; they’re of no interest for audio circuits and are mind-bendingly difficult to understand without some hardcore understanding of inductor and capacitor resonant circuits. Class-G, however, has been exploited in a number of high-power audio amps. In essence, a Class-G amplifier is really a standard Class-AB amplifier but with an additional set of higher voltage power supply rails. The lower voltage rails supply power to the output circuit for signal levels below a particular threshold and thus keep the heat wastage to a minimum. Whenever the audio signal exceeds this threshold the higher supply voltage is electronically switched on to supply the output devices, enabling an even greater output level to be achieved. This technique improves the thermal efficiency when the amplifier is reproducing real-world audio, as the amp, whilst capable of reproducing peak powers of, say, 500W, can automatically throttle back to, say, 50W whenever the peak power isn’t required. Class-H is a variation on Class-G, whereby the higher supply voltage is continuously variable and able to track the shape of the audio peaks by supplying just enough voltage as and when it’s required.

GETTING REAL

A real-world amplifier – whether it’s a mic preamp, a monster PA power amp or part of an equaliser – consists of a number of individual stages or sections that, when combined, represent the complete amplifier design. Earlier I mentioned that all integrated circuit op-amps are Class-AB – this really only expresses the topology of the output stage of the full amplifier circuit. Typically, the complete design will include a Class-A input stage, a Class-A voltage gain stage and a Class-AB output stage. An op-amp is certainly the most ubiquitous amplifier topology, whether packaged into an integrated circuit or built up out of discrete transistors. Most preamps employ an op-amp design and many power amps are also really just a big op-amp. An op-amp is a particular amplifier design that has two inputs and one output plus connections for the power supply. The inputs are referred to as ‘inverting’ and ‘non-inverting’. The inverting, as its name suggests, causes a signal applied to this input to be inverted or phase reversed at the output, whereas the non-inverting input maintains the input-to-output phase relationship. Op-amps have very high gain; typically in the order of 100dB, which in any practical application, is way more than you’d ever require. This enormous gain is reined in through the use of negative feedback – taking a percentage of the output signal and sending it back to the inverting input. This negative feedback reduces the overall gain of the op-amp and indeed can reduce the gain to unity or beyond, even to a gain of zero!

Negative feedback is the great leveller when it comes to amplifier design and is used to reduce a multitude of sins. Whenever negative feedback is employed (and it almost always is) the positive benefits are significant. Output impedance and distortion are lowered while bandwidth is increased. It’s the distortion reduction in particular that enables an amplifier with a Class-AB output stage to achieve very low distortion levels – in the case of some modern integrated op-amps, figures as low as 0.00008% can be achieved with careful implementation.

Ultimately, amplifier performance hinges on the overall design, whether Class-A, Class-AB, valve, transistor or FET, the synergy of the combination of the individual parts and how feedback is employed determines an amplifier’s sonic stamp.

Rob Squire runs Pro Harmonic