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Electronic Circuits and Devices
EC4050
Active Filters
M.Yuvaraj
ACTIVE LOW-PASS FILTERS
• Filters that use op-amps as the active element provide several
advantages over passive filters (R, L, and C elements only).
• The op-amp provides gain, so the signal is not attenuated as it passes
through the filter.
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Single-Pole Filter
• Single-Pole filter provides a roll-off of -20 dB/decade above the
critical frequency
• The critical frequency of the single-pole filter is fc = 1/(2πRC).
• The op-amp in this filter is connected as a noninverting amplifier with
the closed-loop voltage gain in the passband set by the values of R1
and R2.
Sallen-Key Low-Pass Filter
• The Sallen-Key is one of the most common configurations for a secondorder (two-pole) filter, also known as a VCVS (voltage-controlled voltage
source) filter.
• Notice that there are two low-pass RC circuits that
provide a roll-off of -40 dB/decade above the critical
frequency (assuming a Butterworth characteristic).
• A unique feature of the Sallen-Key low-pass filter is
the capacitor that provides feedback for shaping the
response near the edge of the passband.
• The critical frequency for the Sallen-Key filter is
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• The component values can be made equal so that RA = RB = R and CA
= CB = C.
• In this case, the expression for the critical frequency simplifies to
• As in the single-pole filter, the op-amp in the second-order Sallen-Key
filter acts as a noninverting amplifier with the negative feedback
provided by resistors R1 and R2.
• The damping factor is set by the values of R1 and R2, thus making the
filter response either Butterworth, Chebyshev, or Bessel.
• For example, the damping factor of 1.414 required for a second-order
Butterworth response.
Example
• Determine the critical frequency of the Sallen-Key low-pass filter, and
set the value of for an approximate Butterworth response
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Cascaded Low-Pass Filters
ACTIVE HIGH-PASS FILTERS
• Single-Pole Filter
• A high-pass active filter with a -20 dB/decade roll-off.
• The negative feedback circuit is the same as for the low-pass filters.
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The Sallen-Key High-Pass Filter
• The components RA, CA, RB, and CB form the two-pole frequency-selective
circuit.
• Notice that the positions of the resistors and capacitors in the frequencyselective circuit are opposite to those in the low-pass configuration.
• As with the other filters, the response characteristic can be optimized by
proper selection of the feedback resistors, R1 and R2.
Example
• Choose values for the Sallen-Key high-pass filter to implement an
equal-value second-order Butterworth response with a critical
frequency of approximately 10 kHz.
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Cascading High-Pass Filters
ACTIVE BAND-PASS FILTERS
• band-pass filters pass all frequencies bounded by a lower-frequency
limit and an upper-frequency limit and reject all others lying outside
this specified band.
• A band-pass response can be thought of as the overlapping of a lowfrequency response curve and a high-frequency response curve.
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Cascaded Low-Pass and High-Pass Filters
• One way to implement a band-pass filter is a cascaded arrangement
of a high-pass filter and a low-pass filter.
• The critical frequency of each filter is chosen so that the response
curves overlap sufficiently.
• The critical frequency of the high-pass filter must be sufficiently lower
than that of the low-pass stage. This filter is generally limited to wide
bandwidth applications.
• The lower frequency fc1 of the passband is the critical frequency of
the high-pass filter. The upper frequency fc2 is the critical frequency
of the low-pass filter. The center frequency of the passband is the
geometric mean of fc1 and fc2.
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Multiple-Feedback Band-Pass Filter
• The two feedback paths are through R2 and C1.
• Components R1 and C1 provide the low-pass response,
and R2 and C2 provide the high-pass response.
• The maximum gain, A0, occurs at the center frequency
Multiple-Feedback Band-Stop Filter
• Notice that this configuration is similar to the band-pass except that
R3 has been moved and R4 has been added.
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Reference
• Electronics Principles by Albert Malvino and David J Bates
• Electronic Devices by Thomas L Floyed
• Microelectronic circuits by Adel S Sedra, Kenneth Carless Smith 2010,
Oxford University Press
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