南開科技大學圖書館 |

Microwave Circuit Design Using Linear and Nonlinear Techniques.

紀錄類型:	書目-電子資源 : 單行本
正題名/作者:	Microwave Circuit Design Using Linear and Nonlinear Techniques./
作者:	Vendelin, George D.
其他作者:	Pavio, Anthony M.
面頁冊數:	1 online resource (1080 pages)
標題:	Microwave integrated circuits.;Microwave amplifiers.;Oscillators, Microwave.;Electronic circuit design. -
電子資源:	Click to View - 點擊此處查看電子書全文
ISBN:	9780471715825

Microwave Circuit Design Using Linear and Nonlinear Techniques.
Vendelin, George D.

Microwave Circuit Design Using Linear and Nonlinear Techniques. - 2nd ed. - 1 online resource (1080 pages)

Intro -- 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 Elements -- 2.4 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 Classification -- 3.3.2 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.

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 transistor and diode circuits, and also details CAD's usefulness in microwave integrated circuit (MIC) and monolithic microwave integrated circuit (MMIC) technology. Applications of nonlinear SPICE programs, now available for microwave CAD, are described. State-of-the-art coverage includes microwave transistors (HEMTs, MODFETs, MESFETs, HBTs, and more), high-power amplifier design, oscillator design including feedback topologies, phase noise and examples, and more. The techniques presented are illustrated with several MMIC designs, including a wideband amplifier, a low-noise amplifier, and an MMIC mixer. This unique, one-stop handbook also features a major case study of an actual anticollision radar transceiver, which is compared in detail against CAD predictions; examples of actual circuit designs with photographs of completed circuits; and tables of design formulae.

ISBN: 9780471715825Subjects--Topical Terms:

1000121043
Microwave integrated circuits.;Microwave amplifiers.;Oscillators, Microwave.;Electronic circuit design.
Index Terms--Genre/Form:

172687
Electronic books.

LC Class. No.: TK7876.V47 2005

Dewey Class. No.: 621.381/32

Microwave Circuit Design Using Linear and Nonlinear Techniques.
LDR:12487nmm a22004573i 4500 001 1000096999
003 MiAaPQ
005 20190509080016.0
006 m o d |
007 cr cnu||||||||
008 190509s2005 xx o ||||0 eng d
020 $a 9780471715825 $q (electronic bk.)
020 $z 9780471414797
035 $a (MiAaPQ)EBC239395
035 $a (Au-PeEL)EBL239395
035 $a (CaPaEBR)ebr10304359
035 $a (CaONFJC)MIL27664
035 $a (OCoLC)192137052
035 $a EBC239395
040 $a MiAaPQ $b eng $e rda $e pn $c MiAaPQ $d MiAaPQ
050 4 $a TK7876.V47 2005
082 0 $a 621.381/32
100 1 $a Vendelin, George D. $3 1000121042
245 1 0 $a Microwave Circuit Design Using Linear and Nonlinear Techniques.
250 $a 2nd ed.
264 1 $a Hoboken : $b John Wiley & Sons, Incorporated, $c 2005.
264 4 $c ©2005.
300 $a 1 online resource (1080 pages)
336 $a text $b txt $2 rdacontent
337 $a computer $b c $2 rdamedia
338 $a online resource $b cr $2 rdacarrier
505 0 $a Intro -- 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 Elements -- 2.4 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 Classification -- 3.3.2 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.
505 8 $a 4.8 Derivation of Transducer Power Gain -- 4.9 Differential S Parameters -- 4.9.1 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 Networks -- References -- 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 -- 6.6.3 Cavity Resonators -- 6.6.4 Coaxial Dielectric Resonators -- 6.6.5 Thin-Film Bulk-Wave Acoustic Resonator (FBAR) -- References -- Bibliography -- Problems -- 7 NOISE IN LINEAR TWO-PORTS -- 7.1 Introduction -- 7.2 Signal-to-Noise Ratio -- 7.3 Noise Figure Measurements -- 7.4 Noise Parameters and Noise Correlation Matrix -- 7.4.1 Correlation Matrix -- 7.4.2 Method of Combining Two-Port Matrix -- 7.4.3 Noise Transformation Using the [ABCD] Noise Correlation Matrices -- 7.4.4 Relation Between the Noise Parameter and [C(A)].
505 8 $a 7.4.5 Representation of the ABCD Correlation Matrix in Terms of Noise Parameters -- 7.4.6 Noise Correlation Matrix Transformations -- 7.4.7 Matrix Definitions of Series and Shunt Element -- 7.4.8 Transferring All Noise Sources to the Input -- 7.4.9 Transformation of the Noise Sources -- 7.4.10 ABCD Parameters for CE, CC, and CB Configurations -- 7.5 Noisy Two-Port Description -- 7.6 Noise Figure of Cascaded Networks -- 7.7 Influence of External Parasitic Elements -- 7.8 Noise Circles -- 7.9 Noise Correlation in Linear Two-Ports Using Correlation Matrices -- 7.10 Noise Figure Test Equipment -- 7.11 How to Determine Noise Parameters -- 7.12 Calculation of Noise Properties of Bipolar and FETs -- 7.12.1 Hybrid-P Configuration -- 7.12.2 Transformation of Noise Current Source to Input of CE Bipolar Transistor -- 7.12.3 Noise Factor -- 7.12.4 Case of Real Source Impedance -- 7.12.5 Formation of Noise Correlation Matrix of CE Bipolar Transistor -- 7.12.6 Calculation of Noise Parameter Ignoring Base Resistance -- 7.13 Bipolar Transistor Noise Model in T Configuration -- 7.13.1 Real Source Impedance -- 7.13.2 Minimum Noise Factor -- 7.13.3 Noise Correlation Matrix of Bipolar Transistor in T-Equivalent Configuration -- 7.14 The GaAs FET Noise Model -- 7.14.1 Model at Room Temperature -- 7.14.2 Calculation of Noise Parameters -- 7.14.3 Influence of C(gd), R(gs), and R(s) on Noise Parameters -- 7.14.4 Temperature Dependence of Noise Parameters of an FET -- 7.14.5 Approximation and Discussion -- References -- Bibliography -- Problems -- 8 SMALL- AND LARGE-SIGNAL AMPLIFIER DESIGN -- 8.1 Introduction -- 8.2 Single-Stage Amplifier Design -- 8.2.1 High Gain -- 8.2.2 Maximum Available Gain and Unilateral Gain -- 8.2.3 Low-Noise Amplifier -- 8.2.4 High-Power Amplifier -- 8.2.5 Broadband Amplifier -- 8.2.6 Feedback Amplifier -- 8.2.7 Cascode Amplifier.
505 8 $a 8.2.8 Multistage Amplifier -- 8.2.9 Distributed Amplifier and Matrix Amplifier -- 8.2.10 Millimeter-Wave Amplifiers -- 8.3 Frequency Multipliers -- 8.3.1 Introduction -- 8.3.2 Passive Frequency Multiplication -- 8.3.3 Active Frequency Multiplication -- 8.4 Design Example of 1.9-GHz PCS and 2.1-GHz W-CDMA Amplifiers -- 8.5 Stability Analysis and Limitations -- References -- Bibliography -- Problems -- 9 POWER AMPLIFIER DESIGN -- 9.1 Introduction -- 9.2 Device Modeling and Characterization -- 9.3 Optimum Loading -- 9.4 Single-Stage Power Amplifier Design -- 9.5 Multistage Design -- 9.6 Power-Distributed Amplifiers -- 9.7 Class of Operation -- 9.8 Power Amplifier Stability -- 9.9 Amplifier Linearization Methods -- References -- Bibliography -- Problems -- 10 OSCILLATOR DESIGN -- 10.1 Introduction -- 10.2 Compressed Smith Chart -- 10.3 Series or Parallel Resonance -- 10.4 Resonators -- 10.4.1 Dielectric Resonators -- 10.4.2 YIG Resonators -- 10.4.3 Varactor Resonators -- 10.4.4 Ceramic Resonators -- 10.4.5 Resonator Measurements -- 10.5 Two-Port Oscillator Design -- 10.6 Negative Resistance from Transistor Model -- 10.7 Oscillator Q and Output Power -- 10.8 Noise in Oscillators: Linear Approach -- 10.8.1 Using a Spectrum Analyzer -- 10.8.2 Two-Oscillator Method -- 10.8.3 Leeson's Oscillator Model -- 10.8.4 Low-Noise Design -- 10.9 Analytic Approach to Optimum Oscillator Design Using S Parameters -- 10.10 Nonlinear Active Models for Oscillators -- 10.10.1 Diodes with Hyperabrupt Junction -- 10.10.2 Silicon Versus Gallium Arsenide -- 10.10.3 Expressions for g(m) and G(d) -- 10.10.4 Nonlinear Expressions for C(gs), G(gf), and R(i) -- 10.10.5 Analytic Simulation of I-V Characteristics -- 10.10.6 Equivalent-Circuit Derivation -- 10.10.7 Determination of Oscillation Conditions -- 10.10.8 Nonlinear Analysis -- 10.10.9 Conclusion.
505 8 $a 10.11 Oscillator Design Using Nonlinear Cad Tools -- 10.11.1 Parameter Extraction Method -- 10.11.2 Example of Nonlinear Design Methodology: 4-GHz Oscillator-Amplifier -- 10.11.3 Conclusion -- 10.12 Microwave Oscillators Performance -- 10.13 Design of an Oscillator Using Large-Signal Y Parameters -- 10.14 Example for Large-Signal Design Based on Bessel Functions -- 10.15 Design Example for Best Phase Noise and Good Output Power -- 10.16 CAD Solution for Calculating Phase Noise in Oscillators -- 10.16.1 General Analysis of Noise Due to Modulation and Conversion in Oscillators -- 10.16.2 Modulation by a Sinusoidal Signal -- 10.16.3 Modulation by a Noise Signal -- 10.16.4 Oscillator Noise Models -- 10.16.5 Modulation and Conversion Noise -- 10.16.6 Nonlinear Approach for Computation of Noise Analysis of Oscillator Circuits -- 10.16.7 Noise Generation in Oscillators -- 10.16.8 Frequency Conversion Approach -- 10.16.9 Conversion Noise Analysis -- 10.16.10 Noise Performance Index Due to Frequency Conversion -- 10.16.11 Modulation Noise Analysis -- 10.16.12 Noise Performance Index Due to Contribution of Modulation Noise -- 10.16.13 PM-AM Correlation Coefficient -- 10.17 Validation Circuits -- 10.17.1 1000-MHz Ceramic Resonator Oscillator (CRO) -- 10.17.2 4100-MHz Oscillator with Transmission Line Resonators -- 10.17.3 2000-MHz GaAs FET-Based Oscillator -- 10.18 Analytical Approach for Designing Efficient Microwave FET and Bipolar Oscillators (Optimum Power) -- 10.18.1 Series Feedback (MESFET) -- 10.18.2 Parallel Feedback (MESFET) -- 10.18.3 Series Feedback (Bipolar) -- 10.18.4 Parallel Feedback (Bipolar) -- 10.18.5 An FET Example -- 10.18.6 Simulated Results -- 10.18.7 Synthesizers -- 10.18.8 Self-Oscillating Mixer -- References -- Bibliography -- Problems -- 11 MICROWAVE MIXER DESIGN -- 11.1 Introduction -- 11.2 Diode Mixer Theory.
505 8 $a 11.3 Single-Diode Mixers.
520 $a 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 transistor and diode circuits, and also details CAD's usefulness in microwave integrated circuit (MIC) and monolithic microwave integrated circuit (MMIC) technology. Applications of nonlinear SPICE programs, now available for microwave CAD, are described. State-of-the-art coverage includes microwave transistors (HEMTs, MODFETs, MESFETs, HBTs, and more), high-power amplifier design, oscillator design including feedback topologies, phase noise and examples, and more. The techniques presented are illustrated with several MMIC designs, including a wideband amplifier, a low-noise amplifier, and an MMIC mixer. This unique, one-stop handbook also features a major case study of an actual anticollision radar transceiver, which is compared in detail against CAD predictions; examples of actual circuit designs with photographs of completed circuits; and tables of design formulae.
588 $a Description based on publisher supplied metadata and other sources.
590 $a Electronic reproduction. Ann Arbor, Michigan : ProQuest Ebook Central, 2019. Available via World Wide Web. Access may be limited to ProQuest Ebook Central affiliated libraries.
650 0 $a Microwave integrated circuits.;Microwave amplifiers.;Oscillators, Microwave.;Electronic circuit design. $3 1000121043
655 4 $a Electronic books. $2 local. $3 172687
700 1 $a Pavio, Anthony M. $3 1000012326
700 1 $a Rohde, Ulrich L. $3 148800
776 0 8 $i Print version: $a Vendelin, George D. $t Microwave Circuit Design Using Linear and Nonlinear Techniques $d Hoboken : John Wiley & Sons, Incorporated,c2005 $z 9780471414797
797 2 $a ProQuest (Firm)
856 4 0 $u https://ebookcentral.proquest.com/lib/nkut-ebooks/detail.action?docID=239395 $z Click to View - 點擊此處查看電子書全文