Presentation is loading. Please wait.

Presentation is loading. Please wait.

ELECTRIC CIRCUITS EIGHTH EDITION

Published byMagdalene Heath Modified over 7 years ago

Similar presentations

Presentation on theme: "ELECTRIC CIRCUITS EIGHTH EDITION"— Presentation transcript:

1 ELECTRIC CIRCUITS EIGHTH EDITION
JAMES W. NILSSON & SUSAN A. RIEDEL ELECTRIC CIRCUITS EIGHTH EDITION

2 ACTIVE FILTER CIRCUITS
CHAPTER 15 ACTIVE FILTER CIRCUITS © 2008 Pearson Education

3 CONTENTS 15.1 First-Order Low-Pass and High-Pass Filters 15.2 Scaling
15.3 Op Amp Bandpass and Bandreject Filters 15.4 High Order Op Amp Filters 15.5 Narrowband Bandpass and Bandreject Filters © 2008 Pearson Education

4 15.1 First-Order Low-Pass and High-Pass Filters
Active filters consist of op amps, resistors, and capacitors. They can be configured as low-pass, high-pass, bandpass, and bandreject filters. © 2008 Pearson Education

5 15.1 First-Order Low-Pass and High-Pass Filters
They overcome many of the disadvantages associated with passive filters. © 2008 Pearson Education

6 15.1 First-Order Low-Pass and High-Pass Filters
A first-order low-pass filter © 2008 Pearson Education

7 15.1 First-Order Low-Pass and High-Pass Filters
A general op amp circuit © 2008 Pearson Education

8 15.1 First-Order Low-Pass and High-Pass Filters
A first-order high-pass filter © 2008 Pearson Education

9 15.1 First-Order Low-Pass and High-Pass Filters
A prototype low-pass filter has component values of R1 = R2 = 1Ω and C = 1F, and it produces a unity passband gain and a cutoff frequency of 1 rad/s. © 2008 Pearson Education

10 15.1 First-Order Low-Pass and High-Pass Filters
The prototype high-pass filter has same component values and also produces a unity passband gain and a cut-off frequency of 1 rad/s. © 2008 Pearson Education

11 15.2 Scaling Magnitude scaling can be used to alter component values without changing the frequency response of a circuit. © 2008 Pearson Education

12 15.2 Scaling For a magnitude scale factor of km, the scaled (primed) values of resistance, capacitance, and inductance are © 2008 Pearson Education

13 15.2 Scaling Frequency scaling can be used to shift the frequency response of a circuit to another frequency region without changing the overall shape of the frequency response. © 2008 Pearson Education

14 15.2 Scaling For a frequency scale factor of kf , the scaled (primed) values of resistance, capacitance, and inductance are © 2008 Pearson Education

15 15.2 Scaling Components can be scaled in both magnitude and frequency, with the scaled (primed) component values given by © 2008 Pearson Education

16 15.2 Scaling The design of active low-pass and high-pass filters can begin with a prototype filter circuit. Scaling can then be applied to shift the frequency response to the desired cutoff frequency, using component values that are commercially available. © 2008 Pearson Education

17 15.3 Op Amp Bandpass and Bandreject Filters
Constructing the Bode magnitude plot of a bandpass filter © 2008 Pearson Education

18 15.3 Op Amp Bandpass and Bandreject Filters
A cascaded op amp bandpass filter The block diagram The circuit © 2008 Pearson Education

19 15.3 Op Amp Bandpass and Bandreject Filters
An active broadband bandpass filter can be constructed using a cascade of a low-pass filter with the bandpass filter’s upper cutoff frequency, a high-pass filter with the bandpass filter’s lower cutoff frequency, and (optionally) an inverting amplifier gain stage to achieve nonunity gain in the passband. © 2008 Pearson Education

20 15.3 Op Amp Bandpass and Bandreject Filters
Bandpass filters implemented in this fashion must be broadband filters (ωc2 » ωc1), so that the elements of the cascade can be specified independently of one another. © 2008 Pearson Education

21 15.3 Op Amp Bandpass and Bandreject Filters
Example: Designing a Broadband Bandpass Op Amp Filter. Design a bandpass filter for a graphic equalizer to provide an amplification of 2 within the band of frequencies between 100 and 10,000 Hz. Use 0.2µF capacitors. © 2008 Pearson Education

22 15.3 Op Amp Bandpass and Bandreject Filters
Constructing the Bode magnitude plot of a bandreject filter © 2008 Pearson Education

23 15.3 Op Amp Bandpass and Bandreject Filters
An active broadband bandreject filter can be constructed using a parallel combination of a low-pass filter with the bandreject filter’s lower cutoff frequency and a high-pass filter with the bandreject filter’s upper cutoff frequency. © 2008 Pearson Education

24 15.3 Op Amp Bandpass and Bandreject Filters
The outputs are then fed into a summing amplifier, which can produce nonunity gain in the passband. Bandreject filters implemented in this way must be broadband filters (ωc2 » ωc1), so that the low-pass and high-pass filter circuits can be designed independently of one another. © 2008 Pearson Education

25 15.3 Op Amp Bandpass and Bandreject Filters
A parallel op amp bandreject filter The block diagram The circuit © 2008 Pearson Education

26 15.4 Higher Order Op Amp Filters
The bode magnitude plot of a cascade of identical prototype first-order filters © 2008 Pearson Education

27 15.4 Higher Order Op Amp Filters
Higher order active filters have multiple poles in their transfer functions, resulting in a sharper transition from the passband to the stopband and thus a more nearly ideal frequency response. © 2008 Pearson Education

28 15.4 Higher Order Op Amp Filters
A cascade of identical unity-gain low-pass filters. The block diagram The circuit © 2008 Pearson Education

29 15.4 Higher Order Op Amp Filters
The transfer function of an nth–order Butterworth low-pass filter with a cutoff frequency of 1 rad/s can be determined from the equation: © 2008 Pearson Education

30 15.4 Higher Order Op Amp Filters
By Finding the roots of the denominator polynomial. Assigning the left-half plane roots to H(s). Writing the denominator of H(s) as a product of first- and second- order factors. © 2008 Pearson Education

31 15.4 Higher Order Op Amp Filters
Defining the transition region for a low-pass filter © 2008 Pearson Education

32 15.5 Narrowband Bandpass and Bandreject Filters
An active high-Q bandpass filter © 2008 Pearson Education

33 15.5 Narrowband Bandpass and Bandreject Filters
A high-Q active bandreject filter © 2008 Pearson Education

34 15.5 Narrowband Bandpass and Bandreject Filters
If a high-Q, or narrowband, bandpass, or bandreject filter is needed, the cascade or parallel combination will not work. Instead, the circuits shown previously are used with the appropriate design equations. © 2008 Pearson Education

35 THE END © 2008 Pearson Education

Download ppt "ELECTRIC CIRCUITS EIGHTH EDITION"

Similar presentations

Electronic Devices Ninth Edition Floyd Chapter 10.

Electronic Devices Ninth Edition Floyd Chapter 10.
Frequency Characteristics of AC Circuits

Frequency Characteristics of AC Circuits
Active Filters: concepts All input signals are composed of sinusoidal components of various frequencies, amplitudes and phases. If we are interested in.

Active Filters: concepts All input signals are composed of sinusoidal components of various frequencies, amplitudes and phases. If we are interested in.
FREQUENCY SELECTIVE CIRCUITS

FREQUENCY SELECTIVE CIRCUITS
1 Lecture #23 EGR 272 – Circuit Theory II Bode Plots - Recall that there are 5 types of terms in H(s). The first four have already been covered. Read:

1 Lecture #23 EGR 272 – Circuit Theory II Bode Plots - Recall that there are 5 types of terms in H(s). The first four have already been covered. Read:
Lecture 23 Filters Hung-yi Lee.

Lecture 23 Filters Hung-yi Lee.
FILTERS Presented by: Mohammed Alani Supervised By: Dr. Nazila Safavi

FILTERS Presented by: Mohammed Alani Supervised By: Dr. Nazila Safavi
CHAPTER 4: ACTIVE FILTERS.

CHAPTER 4: ACTIVE FILTERS.
Lecture 4 Active Filter (Part I)

Lecture 4 Active Filter (Part I)
Fundamentals of Electric Circuits Chapter 14

Fundamentals of Electric Circuits Chapter 14
Second Order Active Filters Based on Bridged-T Networks

Second Order Active Filters Based on Bridged-T Networks
Lect22EEE 2021 Passive Filters Dr. Holbert April 21, 2008.

Lect22EEE 2021 Passive Filters Dr. Holbert April 21, 2008.
Lecture 231 EEE 302 Electrical Networks II Dr. Keith E. Holbert Summer 2001.

Lecture 231 EEE 302 Electrical Networks II Dr. Keith E. Holbert Summer 2001.
ACTIVE FILTER CIRCUITS. DISADVANTAGES OF PASSIVE FILTER CIRCUITS Passive filter circuits consisting of resistors, inductors, and capacitors are incapable.

ACTIVE FILTER CIRCUITS. DISADVANTAGES OF PASSIVE FILTER CIRCUITS Passive filter circuits consisting of resistors, inductors, and capacitors are incapable.
VARIABLE-FREQUENCY NETWORK

VARIABLE-FREQUENCY NETWORK
Measurement and Instrumentation Dr. Tayab Din Memon Assistant Professor Dept of Electronic Engineering, MUET, Jamshoro. ACTIVE FILTERS and its applications.

Measurement and Instrumentation Dr. Tayab Din Memon Assistant Professor Dept of Electronic Engineering, MUET, Jamshoro. ACTIVE FILTERS and its applications.
ELECTRICAL ENGINEERING: PRINCIPLES AND APPLICATIONS, Fourth Edition, by Allan R. Hambley, ©2008 Pearson Education, Inc. Lecture 19 High Pass Filters, 2.

ELECTRICAL ENGINEERING: PRINCIPLES AND APPLICATIONS, Fourth Edition, by Allan R. Hambley, ©2008 Pearson Education, Inc. Lecture 19 High Pass Filters, 2.
Circuits II EE221 Unit 5 Instructor: Kevin D. Donohue Passive Filters, low-Pass and Band-Pass filters.

Circuits II EE221 Unit 5 Instructor: Kevin D. Donohue Passive Filters, low-Pass and Band-Pass filters.
Advanced Operational Amplifier applications

Advanced Operational Amplifier applications
Lecture 29 Review: Frequency response Frequency response examples Frequency response plots & signal spectra Filters Related educational materials: –Chapter.

Lecture 29 Review: Frequency response Frequency response examples Frequency response plots & signal spectra Filters Related educational materials: –Chapter.

Similar presentations

Ads by Google