Automated Electronic Filter Design

With Emphasis on Distributed Filters
 
 
Springer (Verlag)
  • 2. Auflage
  • |
  • erschienen am 11. August 2018
 
  • Buch
  • |
  • Softcover
  • |
  • IX, 129 Seiten
978-3-319-87110-3 (ISBN)
 

This book describes a novel, efficient and powerful scheme for designing and evaluating the performance characteristics of any electronic filter designed with predefined specifications. The author explains techniques that enable readers to eliminate complicated manual, and thus error-prone and time-consuming, steps of traditional design techniques. The presentation includes demonstration of efficient automation, using an ANSI C language program, which accepts any filter design specification (e.g. Chebyschev low-pass filter, cut-off frequency, pass-band ripple etc.) as input and generates as output a SPICE(Simulation Program with Integrated Circuit Emphasis) format netlist. Readers then can use this netlist to run simulations with any version of the popular SPICE simulator, increasing accuracy of the final results, without violating any of the key principles of the traditional design scheme.

Softcover reprint of the original 2nd ed. 2018
  • Englisch
  • Cham
  • |
  • Schweiz
Springer International Publishing
  • Für Beruf und Forschung
  • Überarbeitete Ausgabe
  • 55
  • |
  • 2 farbige Abbildungen, 55 s/w Abbildungen
  • |
  • 2 Illustrations, color; 55 Illustrations, black and white; IX, 129 p. 57 illus., 2 illus. in color.
  • Höhe: 23.5 cm
  • |
  • Breite: 15.5 cm
  • 226 gr
978-3-319-87110-3 (9783319871103)
10.1007/978-3-319-61554-7
weitere Ausgaben werden ermittelt

Amal Banerjee is an Engineering manager at Analog Electronics in Kolkata, India.

Chapter 1 Introduction and Problem Statement
Chapter 2 Automated Electronic Filter Design Scheme 2.1 The Framework 2.2 Normalized Butterworth Filter 2.3 Practical Normalized Low Pass Butterworth Filter 2.4 Normalized ChebySchev Low Pass Filter 2.5 Normalized Inverse ChebySchev Filter 2.6 Normalized Bessel Filter 2.7 Denormalizing Prototype Filters to Real World Filters 2.7a Frequency Scaling 2.7b Impedance Scaling 2.8 Filter Transformations 2.8a Low Pass to High Pass Filter 2.7b Low Pass to Band Pass Filter 2.9 Automated Filter Design Scheme 2.10 Low Pass to Band Pass Filter Conversion Example
Chapter 3 Automated Electronic Filter Design Algorithm/Scheme Implementation and Design Examples 3,1 Introduction 3.2 Automated Electronic Filter Design Scheme 3.3 Designing Filters with New Scheme 3.3 7th Order Low Pass Butterworth Filter - Simplified Scheme Implementation 3.4 7th Order Low Pass Chebyschev Filter - Simplified Scheme Implementation 3.5 8th Order High Pass Bessel Filter - Simplified Scheme Implementation 3.6 8th Order Band Pass Chebyschev Filter - Simplified Scheme Implementation 3.7 Designing Filters with New Scheme - Full Blown Implementation 3.8 Butterworth Low Pass Filter - Calculated Order 10 Cut-Off Frequency 21 MHz 3.9 Chebyschev High Pass Filter-Calculated Order3 Cut Off Frequency 21 MHz Pass Band Ripple 0.45 dB 3.10 ChebySchev Band Pass Filter - Series Connection of High Pass and Low Pass Filters 3.11 Effect of Non-Ideal Reactive Elements on Filter Behavior and Performance, Design Space Exploration 3.12 SPICE - Electronic Circuit Performance Evaluation Gold Standard
Chapter 4 Higher Frequencies(100's of MHz - 10's of GHz) - Physical Constraints and Distributed Filters 4.1 Terminology 4.2 High Frequency Issues with Discrete Element Electronic Filter Fabrication and Transmission Line Fundamentals 4.2a Lossless Transmission Lines 4.2b Stub Synthesis - Key Equations 4.3 Richard's Transformations and Kuroda's Identities 4.4 Distributed Electronic Filter Design Scheme 4.5 Transmission Line Losses 4.6 Distributed Electronic Filter Design Example Stepped Stepped Impedance Low Pass Filter
Chapter 5 Summary and Conclusion
Appendix A Using the Automated Filter Design Tool
This book describes a novel, efficient and powerful scheme for designing and evaluating the performance characteristics of any electronic filter designed with predefined specifications. The author explains techniques that enable readers to eliminate complicated manual, and thus error-prone and time-consuming, steps of traditional design techniques. The presentation includes demonstration of efficient automation, using an ANSI C language program, which accepts any filter design specification (e.g. Chebyschev low-pass filter, cut-off frequency, pass-band ripple etc.) as input and generates as output a SPICE(Simulation Program with Integrated Circuit Emphasis) format netlist. Readers then can use this netlist to run simulations with any version of the popular SPICE simulator, increasing accuracy of the final results, without violating any of the key principles of the traditional design scheme.

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