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Analog and digital filter design

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Terdapat bibliografi dan indeks.

CONTENTS:
1. Introduction
1.1 Analog Filters
1.2 The Path To Analog Filter Design
1.3 Digital Filters
1.4 Digital Filter Types
1.5 The Path To Digital Filter Design

2. Time And Frequency Response
2.1 Filter Requirements
2.2 The Time Domain
2.3 Analog Filter Normalization
2.4 Normalized Lowpass Responses;
2.5 Bessel Response
2.6 Bessel Normalized Lowpass Filter Component Values
2.7 Butterworth Response
2.8 Butterworth Normalized Lowpass Component Values
2.9 Normalized Component Values for RL >> RS OR RL >> RS
2.10 Normalized Component Values for Source and Load Impedances within a Factor of Ten
2.11 Chebyshev Response
2.12 Normalized Component Values
2.13 Equal Load Normalized Component Value Tables
2.14 Normalized Element Values for Filters with RS = 0 OR RS = ?
2.15 Inverse Chebyshev Response
2.16 Component Values Normalized for 1RAD/S Stopband
2.17 Normalized 3dB Cut-off Frequencies and Passive Component Values
2.18 Cauer Response
2.19 Passive Cauer Filters
2.20 Normalized Cauer Component Values
2.21 The Cut-off Frequency

3. Poles and Zeroes
3.1 Frequency and Time Domain Relationship
3.2 The S-Plane
3.3 Frequency Response and the S-plane
3.4 Impulse Response and the S-plane
3.5 The Laplace Transform - Converting between Time and Frequency Domains
3.6 First Order Filters
3.7 Pole and Zero Locations

4. Analog Lowpass Filters
4.1 Passive Filters
4.2 Formulae for Passive Lowpass Filter De-Normalization
4.3 De-Normalizing Passive Filters with Resonant Elements
4.4 Mains Filter Design
4.5 Active Lowpass Filters
4.6 First Order Filter Section
4.7 Sallen and Key Lowpass Filter
4.8 Denormalizing Sallen and Key Filter Designs
4.9 State Variable Lowpass Filters
4.10 Cauer and Inverse Chebyshev Active Filters
4.11 De-Normalizing State Variable or Biquad Designs
4.12 Frequency Dependant Negative Resistance (FDNR) Filters
4.13 Denormalization of FDNR Filters

5. Highpass Filters
5.1 Passive Filters
5.2 Formulae for Passive Highpass Filter De-Normalization
5.3 Highpass Filters with Transmission Zeroes
5.4 Active Highpass Filters
5.5 First Order Filter Section
5.6 Sallen and Key Highpass Filter
5.7 Using Lowpass Pole to Find Component Values
5.8 Using Highpass Poles to Find Component Values
5.9 Operational Amplifier Requirements
5.10 De-Normalizing Sallen and Key or First Order Designs
5.11 State Variable Highpass Filters
5.12 Cauer and Inverse Chebyshev Active Filters
5.13 Denormalizing State Variable or Biquad Designs
5.14 Gyrator Filters

6. Bandpass Filters
6.1 Lowpass to Bandpass Transformation
6.2 Passive Filters
6.3 Formula for Passive Bandpass Filter De-Normalisation
6.4 Passive Cauer and Inverse Chebyshev Bandpass Filters
6.5 Active Bandpass Filters
6.6 Bandpass Poles and Zeroes
6.7 Bandpass Filter Mid-band Gain
6.8 Multiple Feedback Bandpass Filter
6.9 Denormalising MFBP Active Filter Designs
6.10 Dual Amplifier Bandpass (DABP) Filter
6.11 Denormalising DABP Active Filter Designs
6.12 State Variable Bandpass Filters
6.13 Denormalization of State Variable Design
6.14 Cauer and Inverse Chebyshev Active Filters
6.15 Denormalising Biquad Designs

7. Bandstop Filters
7.1 Passive Filters
7.2 Formula for Passive Bandstop Filter De-Normalization
7.3 Passive Cauer and Inverse Chebyshev Bandstop Filters
7.4 Active Bandstop Filters
7.5 Bandstop Poles and Zeroes
7.6 The Twin Tee Bandstop Filter
7.7 De-Normalization of Twin-tee Notch Filter
7.8 Bandstop Using Multiple Feedback Bandpass Section
7.9 De-Normalization of Bandstop Design Using MFBP Section
7.10 Bandstop Using Dual Amplifier Bandpass (DABP) Section
7.11 De-Normalization of Bandstop Design Using DABP Section
7.12 State Variable Bandstop Filters
7.13 De-Normalization of Bandstop State Variable Filter Section
7.14 Cauer and Inverse Chebyshev Active Filters
7.15 De-Normalization of Bandstop Bi-Quad Filter Section

8. Impedance Matching Networks
8.1 Power Splitters and Diplexer Filters
8.2 Power Splitters and Combiners
8.3 Designing a Diplexer
8.4 Impedance Matching Networks

9. Phase Shift Networks (All-Pass Filters)
9.1 Phase Equalising All-Pass Filters
9.2 Passive First Order Equalisers
9.3 Passive Second Order Equalisers
9.4 Active First Order Equalisers
9.5 Active Second Order Equalisers
9.6 Equalisation of Butterworth and Chebyshev Filters
9.7 Group Delay of Butterworth Filters
9.8 Equalisation of Chebyshev Filters
9.9 Chebyshev Group Delay
9.10 Quadrature Networks and Single Sideband Generation

10. Selecting Components for Analog Filters
10.1 Capacitors
10.2 Inductors
10.3 Resistors
10.4 The Printed Circuit Board (PCB)
10.5 Surface Mount Pcbs
10.6 Assembly and Test
10.7 Operational Amplifiers
10.8 Measurements on Filters

11. Filter Design Software
11.1 Filter Design Programs
11.2 Supplied Software
11.3 Active_F
11.4 Filter2
11.5 Ellipse
11.6 Diplexer
11.7 Match2a

12. Transmission Lines and Printed Circuit Boards as Filters
12.1 Transmission Lines as Filters
12.2 Open Circuit Line
12.3 Short Circuit Line
12.4 Use of Mis-Terminated Lines
12.5 Printed Circuits as Filters
12.6 Bandpass Filters

13. Filters For Phase Locked Loops
13.1 Higher Order Loops
13.2 Analog Versus Digital Phase Locked Loop
13.3 Practical Digital Phase Locked Loop
13.4 Phase Noise
13.5 Capture And Lock Range

14. Filter Integrated Circuits
14.1 Continuous Time Filters
14.2 Switched Capacitor Filters
14.3 Switched Capacitor Filter IC LT1066-1
14.4 An Application of Switched Capacitor Filters
14.5 Resistor Value Calculations
14.6 Synthesizer Filtering

15. Introduction to Digital Filters
15.1 Analog-To-Digital Conversion
15.2 Digital Filtering
15.3 Digital Lowpass Filters
15.4 Truncation (Applied To Fir Filters
15.5 Transforming the Lowpass Response
15.6 DSP Implementation of an Fir Filter
15.7 Introduction to the Infinite Response Filter
15.8 DSP Mathematics
15.9 So, why use a digital filter?

16. Digital FIR Filter Design
16.1 Frequency vs. Time domain responses
16.2 Windows
16.3 FIR Filter Coefficient Calculation
16.4 A Data-Sampling Rate Changer

17. IIR Filter Design
17.1 Bilinear Transformation
17.2 Pre-Warping
17.3 De-Normalization
17.4 IIR Filter Stability
17.5 Design Equations

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Detail Information

Series Title

null

Call Number

621.3815 WIN a

Publisher

Massachusetts : Newnes., 2002

Collation

450 hlm.; ilus.; 25 cm

Language

English

ISBN/ISSN

9780750675475

Classification

621.3815

Content Type

-

Media Type

-

Carrier Type

-

Edition

Second Edition

Subject(s)

Electric Filter-Design and Construction

Specific Detail Info

-

Statement of Responsibility

Steve Winder

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