Sallen Key filter

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A Sallen and Key filter is a type of active filter, particularly valued for its simplicity. The circuit produces a 2-pole (12dB/octave) lowpass or highpass response using two resistors, two capacitors and a unity-gain buffer amplifier. Higher-order filters can be obtained by cascading two or more stages. This filter topology is also known as a voltage controlled voltage source (VCVS) filter. It was introduced by R.P. Sallen and E. L. Key of MIT's Lincoln Laboratory in 1955.

Although the filters depicted here have a passband gain of 1 (or 0 dB), not all Sallen and Key filters have a gain of 1 in the passband. Additional resistors can be added to the op-amp making a non-inverting amplifier with gain greater than 1. Sallen Key filters are relatively resilient to component tolerance, although obtaining high Q factor may require extreme component values or higher gain in the non-inverting amplifier.

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[edit] Low-pass configuration

An example of the unity-gain low-pass configuration is shown below:

Image:Sallen-Key.png

An operational amplifier is used as the buffer here, although an emitter follower is also effective. In general, the cutoff frequency and Q factor are given by the following equations:

F_c = \frac{1}{2\pi\sqrt{R_1R_2C_1C_2}}
Q = \frac{\sqrt{R_1R_2C_1C_2}}{C_2(R_1+R_2)}

Ratio between C_1 and C_2 are n and the ratio between R_1 and R_2 are m, thus :

R1 = mR
R2 = R
C1 = nC
C2 = C
F_c = \frac{1}{2\pi RC\sqrt{mn}}
Q = \frac{\sqrt{mn}}{m+1}

So, for example, the above circuit has an Fc of 15.9 kHz and a Q of 0.5. The transfer function is given by:

H(s)=\frac{1}{1+C_2(R_1+R_2)s+C_1C_2R_1R_2s^2}
H(s)=\frac{1}{1+RC(m+1)s+mnR^2C^2s^2}

[edit] High-pass configuration

An example of the unity gain high-pass filter with an Fc of 72Hz and Q of 0.5 is shown below.

Image:Sallen-Key-hp.png

The relevant equations are:

F_c = \frac{1}{2\pi\sqrt{R_1R_2C_1C_2}}

(as before), and

Q = \frac{R_2C_x}{\sqrt{R_1R_2C_1C_2}}

where

C_x = \frac{C_1C_2}{C_1+C_2}

[edit] Band-pass configuration

An example of the band-pass configuration is shown below:

Image:Sallen-Key_bp.png

Again, an operational amplifier is used as the buffer here, although an emitter follower is also effective. The peak frequency is given by:

F_c=\frac{1}{2\pi}\sqrt{\frac{R_f+R_1}{C_1C_2R_1R_2R_f}}

The voltage divider in the positive feedback loop controls the gain. The "inner gain" G is given by

G=1+\frac{R_b}{R_a}

while the amplifier gain at the peak frequency is given by:

A=\frac{G}{3-G}

It can be seen that G must be kept below 3 or else the filter will oscillate. The filter is usually optimized by selecting R2 = 2R1 and C1 = C2.

[edit] See also

[edit] External links

Op Amps for Everyone - Chapter 16

Real properties of Sallen-Key basic block

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