It is sometimes desirable to have circuits capable of selectively
filtering one frequency or range of frequencies out of a mix of
different frequencies in a circuit. A circuit designed to perform this
frequency selection is called a filter circuit, or simply a filter.
A common need for filter circuits is in high-performance stereo
systems, where certain ranges of audio frequencies need to be amplified
or suppressed for best sound quality and power efficiency. You may be
familiar with equalizers, which allow the amplitudes of several
frequency ranges to be adjusted to suit the listener’s taste and
acoustic properties of the listening area. You may also be familiar with
crossover networks, which block certain ranges of frequencies
from reaching speakers. A tweeter (high-frequency speaker) is
inefficient at reproducing low-frequency signals such as drum beats, so a
crossover circuit is connected between the tweeter and the stereo’s
output terminals to block low-frequency signals, only passing
high-frequency signals to the speaker’s connection terminals. This gives
better audio system efficiency and thus better performance. Both
equalizers and crossover networks are examples of filters, designed to
accomplish filtering of certain frequencies.
Another practical application of filter circuits is in the “conditioning” of non-sinusoidal voltage waveforms in power circuits. Some electronic devices are sensitive to the presence of harmonics in the power supply voltage, and so require power conditioning for proper operation. If a distorted sine-wave voltage behaves like a series of harmonic waveforms added to the fundamental frequency, then it should be possible to construct a filter circuit that only allows the fundamental waveform frequency to pass through, blocking all (higher-frequency) harmonics.
We will be studying the design of several elementary filter circuits in this lesson. To reduce the load of math on the reader, I will make extensive use of SPICE as an analysis tool, displaying Bode plots (amplitude versus frequency) for the various kinds of filters. Bear in mind, though, that these circuits can be analyzed over several points of frequency by repeated series-parallel analysis, much like the previous example with two sources (60 and 90 Hz), if the student is willing to invest a lot of time working and re-working circuit calculations for each frequency.
Another practical application of filter circuits is in the “conditioning” of non-sinusoidal voltage waveforms in power circuits. Some electronic devices are sensitive to the presence of harmonics in the power supply voltage, and so require power conditioning for proper operation. If a distorted sine-wave voltage behaves like a series of harmonic waveforms added to the fundamental frequency, then it should be possible to construct a filter circuit that only allows the fundamental waveform frequency to pass through, blocking all (higher-frequency) harmonics.
We will be studying the design of several elementary filter circuits in this lesson. To reduce the load of math on the reader, I will make extensive use of SPICE as an analysis tool, displaying Bode plots (amplitude versus frequency) for the various kinds of filters. Bear in mind, though, that these circuits can be analyzed over several points of frequency by repeated series-parallel analysis, much like the previous example with two sources (60 and 90 Hz), if the student is willing to invest a lot of time working and re-working circuit calculations for each frequency.
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