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050 4 TK7876.G53 2004
082 0 621.38133
100 1 Giannini, Franco
245 10 Nonlinear Microwave Circuit Design
250 1st ed
264 1 New York :|bJohn Wiley & Sons, Incorporated,|c2004
264 4 |c©2005
300 1 online resource (404 pages)
336 text|btxt|2rdacontent
337 computer|bc|2rdamedia
338 online resource|bcr|2rdacarrier
505 0 Intro -- Nonlinear Microwave Circuit Design -- Contents --
Preface -- Chapter 1 Nonlinear Analysis Methods -- 1.1
Introduction -- 1.2 Time-Domain Solution -- 1.2.1 General
Formulation -- 1.2.2 Steady State Analysis -- 1.2.3
Convolution Methods -- 1.3 Solution Through Series
Expansion -- 1.3.1 Volterra Series -- 1.3.2 Fourier Series
-- 1.3.2.1 Basic formulation (single tone) -- 1.3.2.2
Multi-tone analysis -- 1.3.2.3 Envelope analysis --
1.3.2.4 Additional remarks -- 1.3.2.5 Describing function
-- 1.3.2.6 Spectral balance -- 1.4 The Conversion Matrix -
- 1.5 Bibliography -- Chapter 2 Nonlinear Measurements --
2.1 Introduction -- 2.2 Load/Source Pull -- 2.3 The Vector
Nonlinear Network Analyser -- 2.4 Pulsed Measurements --
2.5 Bibliography -- Chapter 3 Nonlinear Models -- 3.1
Introduction -- 3.2 Physical Models -- 3.2.1 Introduction
-- 3.2.2 Basic Equations -- 3.2.3 Numerical Models --
3.2.4 Analytical Models -- 3.3 Equivalent-Circuit Models -
- 3.3.1 Introduction -- 3.3.2 Linear Models -- 3.3.3 From
Linear to Nonlinear -- 3.3.4 Extraction of an Equivalent
Circuit from Multi-bias Small-signal Measurements -- 3.3.5
Nonlinear Models -- 3.3.6 Packages -- 3.4 Black-Box Models
-- 3.4.1 Table-based Models -- 3.4.2 Quasi-static Model
Identified from Time-domain Data -- 3.4.3 Frequency-domain
Models -- 3.4.4 Behavioural Models -- 3.5 Simplified
Models -- 3.6 Bibliography -- Chapter 4 Power Amplifiers -
- 4.1 Introduction -- 4.2 Classes of Operation -- 4.3
Simplified Class-A Fundamental-frequency Design for High
Efficiency -- 4.3.1 The Methodology -- 4.3.2 An Example of
Application -- 4.4 Multi-harmonic Design for High Power
and Efficiency -- 4.4.1 Introduction -- 4.4.2 Basic
Assumptions -- 4.4.3 Harmonic Tuning Approach -- 4.4.4
Mathematical Statements -- 4.4.5 Design Statements --
4.4.6 Harmonic Generation Mechanisms and Drain Current
Waveforms
505 8 4.4.7 Sample Realisations and Measured Performances -- 4.5
Bibliography -- Chapter 5 Oscillators -- 5.1 Introduction
-- 5.2 Linear Stability and Oscillation Conditions -- 5.3
From Linear to Nonlinear: Quasi-large-signal Oscillation
and Stability Conditions -- 5.4 Design Methods -- 5.5
Nonlinear Analysis Methods for Oscillators -- 5.5.1 The
Probe Approach -- 5.5.2 Nonlinear Methods -- 5.6 Noise --
5.7 Bibliography -- Chapter 6 Frequency Multipliers and
Dividers -- 6.1 Introduction -- 6.2 Passive Multipliers --
6.3 Active Multipliers -- 6.3.1 Introduction -- 6.3.2
Piecewise-linear Analysis -- 6.3.3 Full-nonlinear Analysis
-- 6.3.4 Other Circuit Considerations -- 6.4 Frequency
Dividers - the Regenerative (Passive) Approach -- 6.5
Bibliography -- Chapter 7 Mixers -- 7.1 Introduction --
7.2 Mixer Configurations -- 7.2.1 Passive and Active
Mixers -- 7.2.2 Symmetry -- 7.3 Mixer Design -- 7.4
Nonlinear Analysis -- 7.5 Noise -- 7.6 Bibliography --
Chapter 8 Stability and Injection-locked Circuits -- 8.1
Introduction -- 8.2 Local Stability of Nonlinear Circuits
in Large-signal Regime -- 8.3 Nonlinear Analysis,
Stability and Bifurcations -- 8.3.1 Stability and
Bifurcations -- 8.3.2 Nonlinear Algorithms for Stability
Analysis -- 8.4 Injection Locking -- 8.5 Bibliography --
Appendix -- A.1 Transformation in the Fourier Domain of
the Linear Differential Equation -- A.2 Time-Frequency
Transformations -- A.3 Generalised Fourier Transformation
for the Volterra Series Expansion -- A.4 Discrete Fourier
Transform and Inverse Discrete Fourier Transform for
Periodic Signals -- A.5 The Harmonic Balance System of
Equations for the Example Circuit with N = 3 -- A.6 The
Jacobian Matrix -- A.7 Multi-Dimensional Discrete Fourier
Transform and Inverse Discrete Fourier Transform for Quasi
-periodic Signals
505 8 A.8 Oversampled Discrete Fourier Transform and Inverse
Discrete Fourier Transform for Quasi-Periodic Signals --
A.9 Derivation of Simplified Transport Equations -- A.10
Determination of the Stability of a Linear Network -- A.11
Determination of the Locking Range of an Injection-Locked
Oscillator -- Index
520 "…any reader of 'Nonlinear Microwave Circuit Design' will
gain insight into the many issues that are blissfully
disregarded when using only linear techniques." (IEEE
Microwave Magazine, December 2004)
588 Description based on publisher supplied metadata and other
sources
590 Electronic reproduction. Ann Arbor, Michigan : ProQuest
Ebook Central, 2020. Available via World Wide Web. Access
may be limited to ProQuest Ebook Central affiliated
libraries
650 0 Microwave circuits.;Electric circuits, Nonlinear
655 4 Electronic books
700 1 Leuzzi, Giorgio
776 08 |iPrint version:|aGiannini, Franco|tNonlinear Microwave
Circuit Design|dNew York : John Wiley & Sons, Incorporated,
c2004|z9780470847015
856 40 |uhttps://ebookcentral.proquest.com/lib/sinciatw/
detail.action?docID=219777|zClick to View
