Download presentation
1
Active filters A. V. Gokhale. Y.C.C.E, Nagpur
2
Advantages of active over passive filters
Active filters do not use inductors which are large, heavy and costly elements at audio frequency range. The op-amp used in non-inverting configuration gives high input impedance and low output impedance avoiding loading of source as well as load. In active filters as inductors are not used the quality factor extend upto few hundred. Can be fabricated on chip due to inductor less design. The output in passive filters is always less than input, but in case of active filters the output in pass band is gain times input. Limitations: The high frequency response is restricted by bandwidth and slew rate of op-amp.
3
Classification / Type / Order
Based on frequency available in output as Low pass filter High pass filter Band pass filter Band stop or reject filter.
4
Classification / Type / Order
Type of Active filter: Butterworth filter Chebychev filter Caur filter
5
Classification / Type / Order
Order of Active Filter: Slope of the stop band decides the order of the active filter. Slope given by dB/decade where f2=10xf1 dB/octave where f2=2xf1 dB/decade dB/octave order of filter 20 6 1 40 12 2 60 18 3 80 24 4
6
Transfer function of active filter
An active filter is specified by the voltage transfer function, Under steady state condition i.e. at s = j, where is magnitude or gain of the transfer function and is phase of the transfer function.
7
Normalized Butterworth Polynomial
The order of the filter is given by the normalized denominator of the transfer function known as normalized Butterworth polynomial.
8
First Order Butterwoth Low Pass Filter
The transfer function of the circuit is given by The voltage at non-inverting terminal V1 is given by
9
Transfer function / cut-off frequency
The closed loop gain of the non-inverting amplifier is Thus the transfer function is given by Let
10
Transfer function / cut off frequency
For steady state response substitute where is higher cut-off frequency. The magnitude of the transfer function is given by and the phase angle is given by
11
Frequency Response f =100fH f =10fH f >> fH f = fH f << fH
From the magnitude of transfer function f =100fH f =10fH f >> fH f = fH f << fH Magnitude of TF Frequency The magnitude decreases by 20dB (20x ln 10) each time frequency is increased 10 times. Thus the slope in the stop band will be dB/decade.
12
Frequency response of first order low pass filter
13
First Order Butterwoth High Pass Filter
The transfer function of the circuit is given by The voltage at non-inverting terminal V1 is given by
14
Transfer function / cut-off frequency
The closed loop gain of the non-inverting amplifier is Thus the transfer function is given by Let
15
Transfer function / cut off frequency
For steady state response substitute where is higher cut-off frequency. The magnitude of the transfer function is given by and the phase angle is given by
16
Frequency Response f =fL/100 f =fL/10 f >> fL f = fL
From the magnitude of transfer function f =fL/100 f =fL/10 f >> fL f = fL f << fH Magnitude of TF Frequency The magnitude increases by 20dB (20x ln 10) each time frequency is increased 10 times. Thus the slope in the stop band will be 20dB/decade.
17
Frequency response of first order High pass filter
18
Design Steps for First Order Butterworth Filter Low Pass / High Pass
Design for given cut-off frequency and pass band gain i.e. fL or fH and AF Select value of capacitor less than or equal to 1µF. C 1µF Calculate value of resistor using formula of cut –off frequency For given value of pass band gain calculate value of R1 & RF assuming value of R1 For better performance use RF 100 KΩ
19
Second order Butterworth Filters
1 y1 y3 y4 y2 Vin VA VB Applying KCL at node VB Eq 2 Substitute value of VA in EQ.1 The gain of non-inverting amplifier is given by Applying KCL at node VA Eq 1
20
Generalized Transfer Function of Second Order Filter
Second Order Low Pass Second Order High Pass
21
Second Order Butterworth Low Pass Filter
The generalised transfer function of second order filter is From the figure the admittances are y1=1/R1 y2=1/R2 y3=sC3 y4=sC4
Similar presentations
© 2024 SlidePlayer.com. Inc.
All rights reserved.