Elementary feedback topology The
elementary feedback topology is based on the simple
inverting amplifier configuration. The transfer function is: : H(s) = \frac{V_o}{V_i} = - { Z_2 \over Z_1 } to achieve an unbalanced active implementation of a low-pass transfer function
Multiple feedback topology Multiple feedback topology is an electronic filter topology which is used to implement an
electronic filter by adding two poles to the
transfer function. A diagram of the circuit topology for a second order low pass filter is shown in the figure on the right.
Lowpass The transfer function of the lowpass multiple feedback topology circuit, like all second-order lowpass
linear filters, is: :H(s) = \frac{V_o}{V_i} = -\frac{1}{As^2+Bs+C} = \frac{K {\omega_n}^2}{s^{2}+\frac{\omega_{n}}{Q}s+{\omega_n}^2}. In an MF lowpass filter, :A = R_1 R_3 C_2 C_5\, :B = R_3 C_5 + R_1 C_5 + R_1 R_3 C_5/R_4\, :C = R_1/R_4\, :Q = \frac{ \sqrt{R_3 R_4 C_2 C_5} }{ ( R_4 + R_3 + |K| R_3 ) C_5 } is the
quality factor. :K = -R_4/R_1\, is the DC voltage
gain :\omega_{n} = 2 \pi f_{n} = \frac{1}{ \sqrt{R_3 R_4 C_2 C_5}} is the natural frequency and, provided Q >= \frac{1}{\sqrt{2}} :\omega_{c} = \omega_{n}\sqrt{1-1/(2Q^2)+\sqrt{2-1/Q^2+1/(4Q^4)}} is the cutoff frequency :\omega_{r} = 2 \pi f_{r} = \omega_{n}\sqrt{1-\frac{1}{2Q^2}} is the resonant frequency :M_{r} = \frac{2Q^2}{\sqrt{4Q^2-1}} is the gain peaking at resonance.
Highpass The transfer function of the highpass multiple feedback topology circuit, like all second-order highpass
linear filters, interchanging R and C throughout in the schematic above, is: :H(s) = \frac{V_o}{V_i} = -\frac{s^2}{As^2+Bs+C} = \frac{K s^2}{s^{2}+\frac{\omega_{n}}{Q}s+{\omega_n}^2}. In an MF highpass filter, ignoring the scalar gain factor K: :A=1\, :B= \frac{C_1+C_3+C_4}{R_5 C_3 C_4}\, :C = \frac{1}{R_2 R_5C_3 C_4}\, :Q = \frac{\sqrt{C_3 C_4 R_2 R_5}}{(C_4+C_3+|K|C_3)R_5} is the quality factor :K = -C_1/C_4\, is the HF voltage gain :\omega_{n} = 2 \pi f_{n} = \frac{1}{\sqrt{C_3 C_4 R_2 R_5}} is the natural frequency and again, provided Q >= \frac{1}{\sqrt{2}} :\omega_{c} = 2 \pi f_{c} = \frac{w_{n}}{\sqrt{1-1/(2Q^2)+\sqrt{2-1/Q^2+1/(4Q^4)}}} is the cutoff frequency :\omega_{r} = 2 \pi f_{r} = \frac{\omega_{n}}{\sqrt{1-\frac{1}{2Q^2}}} is the resonant frequency :M_{r} = \frac{2Q^2}{\sqrt{4Q^2-1}} is the gain peaking at resonance.
Bandpass The transfer function of the bandpass multiple feedback topology circuit, like all second-order bandpass
linear filters, is: :H(s) = \frac{V_o}{V_i} = -\frac{s}{A s^2+Bs + C} = \frac{K\omega_{bw}s}{s^2+\omega_{bw}s+\omega_{c}^2}, where :\omega_{c} is the centre frequency, :\omega_{bw} is the filter bandwidth at the -3 dB points, and :Q=\frac{\omega_{c}}{\omega_{bw}} is the quality factor. In an MF bandpass filter with equal capacitors C: :K\omega_{bw} = -\frac{1}{R_{1}C} :A=1 :B=\frac{2C}{R_{3}} :C=\frac{1}{(R_{1}||R_{2})R_{3}C^2} Note that although this is a 2nd-order filter, as it has two poles, the rate of attenuation either side of the centre frequency is 6 dB/octave, not 12 dB/octave, because only one of the poles is active at any given frequency. This topology is only adequate for a narrowband bandpass filter. For a wideband bandpass filter with a flat passband it is necessary to use a lowpass and a highpass in series. For finding suitable component values to achieve the desired filter properties, a similar approach can be followed as in the
Design choices section of the alternative Sallen–Key topology.
Biquad filter topology For the digital implementation of a biquad filter, see Digital biquad filter. A
biquad filter is a type of
linear filter that implements a
transfer function that is the ratio of two
quadratic functions. The name
biquad is short for
biquadratic. Any second-order filter topology can be referred to as a
biquad, such as the MFB or Sallen-Key. However, there is also a specific "biquad" topology. It is also sometimes called the 'ring of 3' circuit. Biquad filters are typically
active and implemented with a
single-amplifier biquad (SAB) or
two-integrator-loop topology. • The SAB topology uses feedback to generate
complex poles and possibly complex
zeros. In particular, the feedback moves the
real poles of an
RC circuit in order to generate the proper filter characteristics. • The two-integrator-loop topology is derived from rearranging a biquadratic transfer function. The rearrangement will equate one signal with the sum of another signal, its integral, and the integral's integral. In other words, the rearrangement reveals a
state variable filter structure. By using different states as outputs, any kind of second-order filter can be implemented. The SAB topology is sensitive to component choice and can be more difficult to adjust. Hence, usually the term
biquad refers to the two-integrator-loop state variable filter topology.
Tow-Thomas filter For example, the basic configuration in Figure 1 can be used as either a
low-pass or
bandpass filter depending on where the output signal is taken from. The second-order low-pass transfer function is given by :H(s)=\frac{G_\mathrm{lpf}{\omega_0}^2}{s^{2}+\frac{\omega_{0}}{Q}s+{\omega_0}^2} where low-pass gain G_\mathrm{lpf}=-R_{2}/R_{1}. The second-order bandpass transfer function is given by :H(s)=\frac{G_\mathrm{bpf}\frac{\omega_{0}}{Q}s}{s^{2}+\frac{\omega_{0}}{Q}s+{\omega_0}^2}. with bandpass gain G_\mathrm{bpf}=-R_{3}/R_{1}. In both cases, the •
Natural frequency is \omega_{0}=1/\sqrt{R_2 R_4 C_1 C_2}. •
Quality factor is Q=\sqrt{\frac{{R_3}^2 C_1}{R_2 R_4 C_2}}. The bandwidth is approximated by B=\omega_{0}/Q, and Q is sometimes expressed as a
damping constant \zeta=1/2Q. If a noninverting low-pass filter is required, the output can be taken at the output of the second
operational amplifier, after the order of the second integrator and the inverter has been switched. If a noninverting bandpass filter is required, the order of the second integrator and the inverter can be switched, and the output taken at the output of the inverter's operational amplifier.
Akerberg-Mossberg filter Figure 2 shows a variant of the Tow-Thomas topology, known as
Akerberg-Mossberg topology, that uses an actively compensated Miller integrator, which improves filter performance.
Sallen–Key topology The Sallen-Key design is a non-inverting second-order filter with the option of high Q and passband gain. ==See also==