Hoboken, NJ, : Wiley, 2005

1-280-27664-9

9786610276646

0-470-35664-2

0-471-71583-2

1-60119-378-5

0-471-71582-4

1 online resource (1080 p.)

PavioAnthony M

RohdeUlrich L

621.38132

621.381320285

Microwave integrated circuits

Microwave amplifiers

Oscillators, Microwave

Electronic circuit design

Inglese

Description based upon print version of record.

Includes bibliographical references and index.

MICROWAVE CIRCUIT DESIGN USING LINEAR AND NONLINEAR TECHNIQUES; CONTENTS; FOREWORD; PREFACE; 1 RF/MICROWAVE SYSTEMS; 1.1 Introduction; 1.2 Maxwell's Equations; 1.3 RF Wireless/Microwave/Millimeter-Wave Applications; 1.4 Frequency Bands, Modes, and Waveforms of Operation; 1.5 Analog and Digital Requirements; 1.6 Elementary Definitions; 1.7 Basic RF Transmitters and Receivers; 1.8 Modern CAD for Nonlinear Circuit Analysis; 1.9 Dynamic Load Line; References; Bibliography; Problems; 2 LUMPED AND DISTRIBUTED ELEMENTS; 2.1 Introduction; 2.2 Transition from RF to Microwave Circuits

2.3 Parasitic Effects on Lumped Elements2.4 Distributed Elements; 2.5

Hybrid Element: Helical Coil; References; Bibliography; Problems; 3 ACTIVE DEVICES; 3.1 Introduction; 3.2 Diodes; 3.2.1 Large-Signal Diode Model; 3.2.2 Mixer and Detector Diodes; 3.2.3 Parameter Trade-Offs; 3.2.4 Mixer Diodes; 3.2.5 pin Diodes; 3.2.6 Tuning Diodes; 3.2.7 Abrupt Junction; 3.2.8 Linearly Graded Junction; 3.2.9 Hyperabrupt Junction; 3.2.10 Silicon Versus Gallium Arsenide; 3.2.11 Q Factor or Diode Loss; 3.2.12 Diode Problems; 3.2.13 Diode-Tuned Resonant Circuits; Tuning Range; 3.3 Microwave Transistors

3.3.1 Transistor Classification3.3.2 Transistor Structure Types; 3.3.3 dc Model of BJT; 3.4 Heterojunction Bipolar Transistor; 3.5 Microwave FET; 3.5.1 MOSFETs; 3.5.2 Gallium Arsenide MESFETs; 3.5.3 HEMT; 3.5.4 Foundry Services; References; Bibliography; Problems; 4 TWO-PORT NETWORKS; 4.1 Introduction; 4.2 Two-Port Parameters; 4.3 S Parameters; 4.4 S Parameters from SPICE Analysis; 4.5 Stability; 4.6 Power Gains, Voltage Gain, and Current Gain; 4.6.1 Power Gain; 4.6.2 Voltage Gain and Current Gain; 4.6.3 Current Gain; 4.7 Three-Ports; 4.8 Derivation of Transducer Power Gain

4.9 Differential S Parameters4.9.1 Measurements; 4.9.2 Example; 4.10 Twisted-Wire Pair Lines; 4.11 Low-Noise and High-Power Amplifier Design; 4.12 Low-Noise Amplifier Design Examples; References; Bibliography; Problems; 5 IMPEDANCE MATCHING; 5.1 Introduction; 5.2 Smith Charts and Matching; 5.3 Impedance Matching Networks; 5.4 Single-Element Matching; 5.5 Two-Element Matching; 5.6 Matching Networks Using Lumped Elements; 5.7 Matching Networks Using Distributed Elements; 5.7.1 Twisted-Wire Pair Transformers; 5.7.2 Transmission Line Transformers; 5.7.3 Tapered Transmission Lines

5.8 Bandwidth Constraints for Matching NetworksReferences; Bibliography; Problems; 6 MICROWAVE FILTERS; 6.1 Introduction; 6.2 Low-Pass Prototype Filter Design; 6.2.1 Butterworth Response; 6.2.2 Chebyshev Response; 6.3 Transformations; 6.3.1 Low-Pass Filters: Frequency and Impedance Scaling; 6.3.2 High-Pass Filters; 6.3.3 Bandpass Filters; 6.3.4 Narrow-Band Bandpass Filters; 6.3.5 Band-Stop Filters; 6.4 Transmission Line Filters; 6.4.1 Semilumped Low-Pass Filters; 6.4.2 Richards Transformation; 6.5 Exact Designs and CAD Tools; 6.6 Real-Life Filters; 6.6.1 Lumped Elements

6.6.2 Transmission Line Elements

The ultimate handbook on microwave circuit design with CAD. Full of tips and insights from seasoned industry veterans, Microwave Circuit Design offers practical, proven advice on improving the design quality of microwave passive and active circuits-while cutting costs and time. Covering all levels of microwave circuit design from the elementary to the very advanced, the book systematically presents computer-aided methods for linear and nonlinear designs used in the design and manufacture of microwave amplifiers, oscillators, and mixers. Using the newest CAD tools, the book shows how to design