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Different designs of amplifier are used for different types of applications and signals. We can broadly divide amplifiers into three categories—small signal amplifiers, low frequency power amplifiers and RF power amplifiers. Each of these calls for a slightly different design approach, mainly because of the physical limitations of the components used to implement the amplifier, and the efficiencies that can be realised.
Amplifiers can be implemented using transistors of various types, or vacuum tubes (valves). Other more exotic forms of amplifier are also possible using different types of devices, but these will not be discussed in detail here to avoid complicating the picture too much. Such exotic amplifiers are often used for microwave or other extremely high frequency signals.
Amplifier circuits are classified as A, B, AB and C for analogue designs, and class D and E for switching designs. For the analogue classes, each class defines what proportion of the input signal cycle is used to actually switch on the amplifying device:
This can be most easily understood using the diagrams in each section below. For the sake of illustration, a bipolar junction transistor is shown as the amplifying device, but in practice this could be a MOSFET or vacuum tube device. In an analogue amplifier, the signal is applied to the input terminal of the device (base, gate or grid), and this causes a current to flow in proportion to the input between the output terminal and ground (collector, drain or anode). This current is obtained from the power supply. The voltage signal shown is thus a larger version of the input, but has been changed in sign (inverted) by the amplification. Other arrangements of amplifying device are possible, but that given ( common emitter, common source or common cathode ) is the easiest to understand and employ in practice. If the amplifying element is linear, then the output will be faithful copy of the input, only larger and inverted. In practice, transistors are not linear, and the output will only approximate the input. This is the origin of distortion within an amplifier. Which class of amplifier (A, B, AB or C) depends on how the amplifying device is biased—in the diagrams the bias circuits are omitted for clarity.
Any real amplifier is an imperfect realization of an ideal amplifier. One important limitation of a real amplifier is that the output it can generate is ultimately limited by the power available from the power supply. An amplifier can saturate and clip the output if the input signal becomes too large for the amplifier to reproduce.
Class A amplifiers amplify over the whole of the input cycle. They are the usual means of implementing small-signal amplifiers. They are not very efficient—a theoretical maximum of 50% is obtainable, but for small signals, this waste of power is still extremely small, and can easily be tolerated. It is only when we need to create output powers with appreciable levels of voltage and current does Class A become problematic. In a Class A circuit, the amplifying element is biased such that the device is always conducting to some extent, and is operated over the most linear portion of its characteristic curve (known as its transfer functionA transfer function is a mathematical representation of the relation between the input and output of a linear time-invariant system. It is mainly used in linear system theory, signal processing, communications theory, and control theory. Signal processing or transconductanceTransconductance is a property of certain electronic components. It is a contraction of "transfer conductance". Whereas conductance is the creation of a current through two points where a voltage is applied, transconductance is the creation of a current t curve). Because the device is always conducting, even if there is no input at all, power is wasted. This is the reason for its inefficiency.
If we wish to produce large output powers from a Class A circuit, the power wastage will become significant. For every wattThe watt (symbol: W is the SI derived unit for power. It is equivalent to 1 joule per second (1 J/s), or in electrical units, 1 volt- ampere (1 V · A). It is the rate in joules per second at which energy is being converted, used or dissipated. Equations : delivered to the load, the amplifier itself will, at best, waste another watt. For large powers this will call for a large power supply and large heat sink to carry away the waste heat. Class A designs have largely been superseded for audioAudio can mean: sound that can be heard electronic or other signals of frequencies audible to humans (about 20--20,000 Hz) broadcasting or reception of sound high-fidelity sound reproduction sound recording and reproduction in general "I hear" in the Lati power amplifiers, though some audiophileAn audiophile most generally, is a lover of sound or music, but the word is more commonly used about someone who cares about hi-fi playback of sound recordings, rather than live performances. In some cases, an audiophile desires an improvement in the souns believe that Class A gives the best sound quality, due to it being operated in as linear a manner as possible. In addition, some aficionados prefer vacuum tube designs over transistors, for a number of reasons. One is that the characteristic curve of a valve means that distortion tends to be in the form of even harmonicIn acoustics and telecommunication, the harmonic of a wave is a component frequency of the signal that is an integral multiple of the fundamental frequency. For a sine wave, it is an integral multiple of the frequency of the wave. For example, if the freqs, which, they claim, sound more "musical" than odd harmonics. Another is that valves use many more electronThe electron (also called negatron commonly represented as e&minus is a subatomic particle. In an atom the electrons surround the nucleus of protons and neutrons in an electron configuration. Electrons have the smallest electrical charge and when they movs at once than a transistor, and so statistical effects lead to a "smoother" approximation of the true waveform—see shot noiseShot noise consists of random fluctuations of the electric current in an electrical conductor, which are caused by the fact that the current is carried by discrete charges ( electrons). The strength of this noise increases for growing magnitude of the ave for more on this. Field-effect transistors have similar characteristics to valves, so these are found more often in high quality amplifiers than bipolar transistors. Historically, valve amplifiers often used a Class A power amplifier simply because valves are large and expensive; the Class A design uses only a single device. Transistors are much cheaper, and so more elaborate designs that give greater efficiency but use more parts are still cost effective.