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RF and microwave circuit design : theory and applications / / Charles E. Free, Colin S. Aitchison
RF and microwave circuit design : theory and applications / / Charles E. Free, Colin S. Aitchison
Autore Free Charles E.
Pubbl/distr/stampa Hoboken, New Jersey : , : John Wiley & Sons, Inc., , [2022]
Descrizione fisica 1 online resource (531 pages)
Disciplina 621.38412
Collana Microwave and Wireless Technologies Series
Soggetto topico Radio circuits - Design and construction
Microwave circuits - Design and construction
ISBN 1-119-11467-5
1-119-11466-7
1-119-33223-0
Formato Materiale a stampa
Livello bibliografico Monografia
Lingua di pubblicazione eng
Nota di contenuto Cover -- Title Page -- Copyright -- Contents -- Preface -- About the Companion Website -- Chapter 1 RF Transmission Lines -- 1.1 Introduction -- 1.2 Voltage, Current, and Impedance Relationships on a Transmission Line -- 1.3 Propagation Constant -- 1.3.1 Dispersion -- 1.3.2 Amplitude Distortion -- 1.4 Lossless Transmission Lines -- 1.5 Matched and Mismatched Transmission Lines -- 1.6 Waves on a Transmission Line -- 1.7 The Smith Chart -- 1.7.1 Derivation of the Smith Chart -- 1.7.2 Properties of the Smith Chart -- 1.8 Stubs -- 1.9 Distributed Matching Circuits -- 1.10 Manipulation of Lumped Impedances Using the Smith Chart -- 1.11 Lumped Impedance Matching -- 1.11.1 Matching a Complex Load Impedance to a Real Source Impedance -- 1.11.2 Matching a Complex Load Impedance to a Complex Source Impedance -- 1.12 Equivalent Lumped Circuit of a Lossless Transmission Line -- 1.13 Supplementary Problems -- Appendix 1.A Coaxial Cable -- 1.A.1 Electromagnetic Field Patterns in Coaxial Cable -- 1.A.2 Essential Properties of Coaxial Cables -- Appendix 1.B Coplanar Waveguide -- 1.B.1 Structure of Coplanar Waveguide (CPW) -- 1.B.2 Electromagnetic Field Distribution on a CPW Line -- 1.B.3 Essential Properties of Coplanar (CPW) Lines -- 1.B.4 Summary of Key Points Relating to CPW Lines -- Appendix 1.C Metal Waveguide -- 1.C.1 Waveguide Principles -- 1.C.2 Waveguide Propagation -- 1.C.3 Rectangular Waveguide Modes -- 1.C.4 The Waveguide Equation -- 1.C.5 Phase and Group Velocities -- 1.C.6 Field Theory Analysis of Rectangular Waveguides -- 1.C.7 Waveguide Impedance -- 1.C.8 Higher‐Order Rectangular Waveguide Modes -- 1.C.9 Waveguide Attenuation -- 1.C.10 Sizes of Rectangular Waveguide and Waveguide Designation -- 1.C.11 Circular Waveguide -- References -- Chapter 2 Planar Circuit Design I -- 2.1 Introduction.
2.2 Electromagnetic Field Distribution Across a Microstrip Line -- 2.3 Effective Relative Permittivity, εr,eff MSTRIP -- 2.4 Microstrip Design Graphs and CAD Software -- 2.5 Operating Frequency Limitations -- 2.6 Skin Depth -- 2.7 Examples of Microstrip Components -- 2.7.1 Branch‐Line Coupler -- 2.7.2 Quarter‐Wave Transformer -- 2.7.3 Wilkinson Power Divider -- 2.8 Microstrip Coupled‐Line Structures -- 2.8.1 Analysis of Microstrip Coupled Lines -- 2.8.2 Microstrip Directional Couplers -- 2.8.2.1 Design of Microstrip Directional Couplers -- 2.8.2.2 Directivity of Microstrip Directional Couplers -- 2.8.2.3 Improvements to Microstrip Directional Couplers -- 2.8.3 Examples of Other Common Microstrip Coupled‐Line Structures -- 2.8.3.1 Microstrip DC Break -- 2.8.3.2 Edge‐Coupled Microstrip Band‐Pass Filter -- 2.8.3.3 Lange Coupler -- 2.9 Summary -- 2.10 Supplementary Problems -- References -- Chapter 3 Fabrication Processes for RF and Microwave Circuits -- 3.1 Introduction -- 3.2 Review of Essential Material Parameters -- 3.2.1 Dielectrics -- 3.2.2 Conductors -- 3.3 Requirements for RF Circuit Materials -- 3.4 Fabrication of Planar High‐Frequency Circuits -- 3.4.1 Etched Circuits -- 3.4.2 Thick‐Film Circuits (Direct Screen Printed) -- 3.4.3 Thick Film Circuits (Using Photoimageable Materials) -- 3.4.4 Low‐Temperature Co‐Fired Ceramic Circuits -- 3.5 Use of Ink Jet Technology -- 3.6 Characterization of Materials for RF and Microwave Circuits -- 3.6.1 Measurement of Dielectric Loss and Dielectric Constant -- 3.6.1.1 Cavity Resonators -- 3.6.1.2 Dielectric Characterization by Cavity Perturbation -- 3.6.1.3 Use of the Split Post Dielectric Resonator (SPDR) -- 3.6.1.4 Open Resonator -- 3.6.1.5 Free‐Space Transmission Measurements -- 3.6.2 Measurement of Planar Line Properties -- 3.6.2.1 The Microstrip Resonant Ring -- 3.6.2.2 Non‐resonant Lines.
3.6.3 Physical Properties of Microstrip Lines -- 3.7 Supplementary Problems -- References -- Chapter 4 Planar Circuit Design II -- 4.1 Introduction -- 4.2 Discontinuities in Microstrip -- 4.2.1 Open‐End Effect -- 4.2.2 Step‐Width -- 4.2.3 Corners -- 4.2.4 Gaps -- 4.2.5 T‐Junctions -- 4.3 Microstrip Enclosures -- 4.4 Packaged Lumped‐Element Passive Components -- 4.4.1 Typical Packages for RF Passive Components -- 4.4.2 Lumped‐Element Resistors -- 4.4.3 Lumped‐Element Capacitors -- 4.4.4 Lumped‐Element Inductors -- 4.5 Miniature Planar Components -- 4.5.1 Spiral Inductors -- 4.5.2 Loop Inductors -- 4.5.3 Interdigitated Capacitors -- 4.5.4 Metal-Insulator-Metal Capacitor -- References -- Chapter 5 S‐Parameters -- 5.1 Introduction -- 5.2 S‐Parameter Definitions -- 5.3 Signal Flow Graphs -- 5.4 Mason's Non‐touching Loop Rule -- 5.5 Reflection Coefficient of a Two‐Port Network -- 5.6 Power Gains of Two‐Port Networks -- 5.7 Stability -- 5.8 Supplementary Problems -- {5.A.1} Transmission Parameters (ABCD Parameters) -- {5.A.2} Admittance Parameters (Y‐Parameters) -- {5.A.3} Impedance Parameters (Z‐Parameters) -- References -- Chapter 6 Microwave Ferrites -- 6.1 Introduction -- 6.2 Basic Properties of Ferrite Materials -- 6.2.1 Ferrite Materials -- 6.2.2 Precession in Ferrite Materials -- 6.2.3 Permeability Tensor -- 6.2.4 Faraday Rotation -- 6.3 Ferrites in Metallic Waveguide -- 6.3.1 Resonance Isolator -- 6.3.2 Field Displacement Isolator -- 6.3.3 Waveguide Circulator -- 6.4 Ferrites in Planar Circuits -- 6.4.1 Planar Circulators -- 6.4.2 Edge‐Guided‐Mode Propagation -- 6.4.3 Edge‐Guided‐Mode Isolator -- 6.4.4 Phase Shifters -- 6.5 Self‐Biased Ferrites -- 6.6 Supplementary Problems -- References -- Chapter 7 Measurements -- 7.1 Introduction -- 7.2 RF and Microwave Connectors -- 7.2.1 Maintenance of Connectors -- 7.2.2 Connecting to Planar Circuits.
7.3 Microwave Vector Network Analyzers -- 7.3.1 Description and Configuration -- 7.3.2 Error Models Representing a VNA -- 7.3.3 Calibration of a VNA -- 7.4 On‐Wafer Measurements -- 7.5 Summary -- References -- Chapter 8 RF Filters -- 8.1 Introduction -- 8.2 Review of Filter Responses -- 8.3 Filter Parameters -- 8.4 Design Strategy for RF and Microwave Filters -- 8.5 Multi‐Element Low‐Pass Filter -- 8.6 Practical Filter Responses -- 8.7 Butterworth (or Maximally Flat) Response -- 8.7.1 Butterworth Low‐Pass Filter -- 8.7.2 Butterworth High‐Pass Filter -- 8.7.3 Butterworth Band‐Pass Filter -- 8.8 Chebyshev (Equal Ripple) Response -- 8.9 Microstrip Low‐Pass Filter, Using Stepped Impedances -- 8.10 Microstrip Low‐Pass Filter, Using Stubs -- 8.11 Microstrip Edge‐Coupled Band‐Pass Filters -- 8.12 Microstrip End‐Coupled Band‐Pass Filters -- 8.13 Practical Points Associated with Filter Design -- 8.14 Summary -- 8.15 Supplementary Problems -- References -- Chapter 9 Microwave Small‐Signal Amplifiers -- 9.1 Introduction -- 9.2 Conditions for Matching -- 9.3 Distributed (Microstrip) Matching Networks -- 9.4 DC Biasing Circuits -- 9.5 Microwave Transistor Packages -- 9.6 Typical Hybrid Amplifier -- 9.7 DC Finger Breaks -- 9.8 Constant Gain Circles -- 9.9 Stability Circles -- 9.10 Noise Circles -- 9.11 Low‐Noise Amplifier Design -- 9.12 Simultaneous Conjugate Match -- 9.13 Broadband Matching -- 9.14 Summary -- 9.15 Supplementary Problems -- References -- Chapter 10 Switches and Phase Shifters -- 10.1 Introduction -- 10.2 Switches -- 10.2.1 PIN Diodes -- 10.2.2 Field Effect Transistors -- 10.2.3 Microelectromechanical Systems -- 10.2.4 Inline Phase Change Switch Devices -- 10.3 Digital Phase Shifters -- 10.3.1 Switched‐Path Phase Shifter -- 10.3.2 Loaded‐Line Phase Shifter -- 10.3.3 Reflection‐Type Phase Shifter -- 10.3.4 Schiffman 90° Phase Shifter.
10.3.5 Single‐Switch Phase Shifter -- 10.4 Supplementary Problems -- References -- Chapter 11 Oscillators -- 11.1 Introduction -- 11.2 Criteria for Oscillation in a Feedback Circuit -- 11.3 RF (Transistor) Oscillators -- 11.3.1 Colpitts Oscillator -- 11.3.2 Hartley Oscillator -- 11.3.3 Clapp-Gouriet Oscillator -- 11.4 Voltage‐Controlled Oscillator -- 11.5 Crystal‐Controlled Oscillators -- 11.5.1 Crystals -- 11.5.2 Crystal‐Controlled Oscillators -- 11.6 Frequency Synthesizers -- 11.6.1 The Phase‐Locked Loop -- 11.6.1.1 Principle of a Phase‐Locked Loop -- 11.6.1.2 Main Components of a Phase‐Locked Loop -- 11.6.1.3 Gain of Phase‐Locked Loop -- 11.6.1.4 Transient Analysis of a Phase‐Locked Loop -- 11.6.2 Indirect Frequency Synthesizer Circuits -- 11.7 Microwave Oscillators -- 11.7.1 Dielectric Resonator Oscillator -- 11.7.2 Delay‐Line Stabilized Microwave Oscillators -- 11.7.3 Diode Oscillators -- 11.7.3.1 Gunn Diode Oscillator -- 11.7.3.2 IMPATT Diode Oscillator -- 11.8 Oscillator Noise -- 11.9 Measurement of Oscillator Noise -- 11.10 Supplementary Problems -- References -- Chapter 12 RF and Microwave Antennas -- 12.1 Introduction -- 12.2 Antenna Parameters -- 12.3 Spherical Polar Coordinates -- 12.4 Radiation from a Hertzian Dipole -- 12.4.1 Basic Principles -- 12.4.2 Gain of a Hertzian Dipole -- 12.5 Radiation from a Half‐Wave Dipole -- 12.5.1 Basic Principles -- 12.5.2 Gain of a Half‐Wave Dipole -- 12.5.3 Summary of the Properties of a Half‐Wave Dipole -- 12.6 Antenna Arrays -- 12.7 Mutual Impedance -- 12.8 Arrays Containing Parasitic Elements -- 12.9 Yagi-Uda Antenna -- 12.10 Log‐Periodic Array -- 12.11 Loop Antenna -- 12.12 Planar Antennas -- 12.12.1 Linearly Polarized A linearly polarized antenna is one where the direction of the radiated electric field remains fixed as the wave propagates. Patch Antennas.
12.12.2 Circularly Polarized Planar Antennas.
Record Nr. UNINA-9910555132003321
Free Charles E.  
Hoboken, New Jersey : , : John Wiley & Sons, Inc., , [2022]
Materiale a stampa
Lo trovi qui: Univ. Federico II
Opac: Controlla la disponibilità qui
RF and microwave circuit design : theory and applications / / Charles E. Free, Colin S. Aitchison
RF and microwave circuit design : theory and applications / / Charles E. Free, Colin S. Aitchison
Autore Free Charles E.
Pubbl/distr/stampa Hoboken, New Jersey : , : John Wiley & Sons, Inc., , [2022]
Descrizione fisica 1 online resource (531 pages)
Disciplina 621.38412
Collana Microwave and Wireless Technologies Series
Soggetto topico Radio circuits - Design and construction
Microwave circuits - Design and construction
ISBN 1-119-11467-5
1-119-11466-7
1-119-33223-0
Formato Materiale a stampa
Livello bibliografico Monografia
Lingua di pubblicazione eng
Nota di contenuto Cover -- Title Page -- Copyright -- Contents -- Preface -- About the Companion Website -- Chapter 1 RF Transmission Lines -- 1.1 Introduction -- 1.2 Voltage, Current, and Impedance Relationships on a Transmission Line -- 1.3 Propagation Constant -- 1.3.1 Dispersion -- 1.3.2 Amplitude Distortion -- 1.4 Lossless Transmission Lines -- 1.5 Matched and Mismatched Transmission Lines -- 1.6 Waves on a Transmission Line -- 1.7 The Smith Chart -- 1.7.1 Derivation of the Smith Chart -- 1.7.2 Properties of the Smith Chart -- 1.8 Stubs -- 1.9 Distributed Matching Circuits -- 1.10 Manipulation of Lumped Impedances Using the Smith Chart -- 1.11 Lumped Impedance Matching -- 1.11.1 Matching a Complex Load Impedance to a Real Source Impedance -- 1.11.2 Matching a Complex Load Impedance to a Complex Source Impedance -- 1.12 Equivalent Lumped Circuit of a Lossless Transmission Line -- 1.13 Supplementary Problems -- Appendix 1.A Coaxial Cable -- 1.A.1 Electromagnetic Field Patterns in Coaxial Cable -- 1.A.2 Essential Properties of Coaxial Cables -- Appendix 1.B Coplanar Waveguide -- 1.B.1 Structure of Coplanar Waveguide (CPW) -- 1.B.2 Electromagnetic Field Distribution on a CPW Line -- 1.B.3 Essential Properties of Coplanar (CPW) Lines -- 1.B.4 Summary of Key Points Relating to CPW Lines -- Appendix 1.C Metal Waveguide -- 1.C.1 Waveguide Principles -- 1.C.2 Waveguide Propagation -- 1.C.3 Rectangular Waveguide Modes -- 1.C.4 The Waveguide Equation -- 1.C.5 Phase and Group Velocities -- 1.C.6 Field Theory Analysis of Rectangular Waveguides -- 1.C.7 Waveguide Impedance -- 1.C.8 Higher‐Order Rectangular Waveguide Modes -- 1.C.9 Waveguide Attenuation -- 1.C.10 Sizes of Rectangular Waveguide and Waveguide Designation -- 1.C.11 Circular Waveguide -- References -- Chapter 2 Planar Circuit Design I -- 2.1 Introduction.
2.2 Electromagnetic Field Distribution Across a Microstrip Line -- 2.3 Effective Relative Permittivity, εr,eff MSTRIP -- 2.4 Microstrip Design Graphs and CAD Software -- 2.5 Operating Frequency Limitations -- 2.6 Skin Depth -- 2.7 Examples of Microstrip Components -- 2.7.1 Branch‐Line Coupler -- 2.7.2 Quarter‐Wave Transformer -- 2.7.3 Wilkinson Power Divider -- 2.8 Microstrip Coupled‐Line Structures -- 2.8.1 Analysis of Microstrip Coupled Lines -- 2.8.2 Microstrip Directional Couplers -- 2.8.2.1 Design of Microstrip Directional Couplers -- 2.8.2.2 Directivity of Microstrip Directional Couplers -- 2.8.2.3 Improvements to Microstrip Directional Couplers -- 2.8.3 Examples of Other Common Microstrip Coupled‐Line Structures -- 2.8.3.1 Microstrip DC Break -- 2.8.3.2 Edge‐Coupled Microstrip Band‐Pass Filter -- 2.8.3.3 Lange Coupler -- 2.9 Summary -- 2.10 Supplementary Problems -- References -- Chapter 3 Fabrication Processes for RF and Microwave Circuits -- 3.1 Introduction -- 3.2 Review of Essential Material Parameters -- 3.2.1 Dielectrics -- 3.2.2 Conductors -- 3.3 Requirements for RF Circuit Materials -- 3.4 Fabrication of Planar High‐Frequency Circuits -- 3.4.1 Etched Circuits -- 3.4.2 Thick‐Film Circuits (Direct Screen Printed) -- 3.4.3 Thick Film Circuits (Using Photoimageable Materials) -- 3.4.4 Low‐Temperature Co‐Fired Ceramic Circuits -- 3.5 Use of Ink Jet Technology -- 3.6 Characterization of Materials for RF and Microwave Circuits -- 3.6.1 Measurement of Dielectric Loss and Dielectric Constant -- 3.6.1.1 Cavity Resonators -- 3.6.1.2 Dielectric Characterization by Cavity Perturbation -- 3.6.1.3 Use of the Split Post Dielectric Resonator (SPDR) -- 3.6.1.4 Open Resonator -- 3.6.1.5 Free‐Space Transmission Measurements -- 3.6.2 Measurement of Planar Line Properties -- 3.6.2.1 The Microstrip Resonant Ring -- 3.6.2.2 Non‐resonant Lines.
3.6.3 Physical Properties of Microstrip Lines -- 3.7 Supplementary Problems -- References -- Chapter 4 Planar Circuit Design II -- 4.1 Introduction -- 4.2 Discontinuities in Microstrip -- 4.2.1 Open‐End Effect -- 4.2.2 Step‐Width -- 4.2.3 Corners -- 4.2.4 Gaps -- 4.2.5 T‐Junctions -- 4.3 Microstrip Enclosures -- 4.4 Packaged Lumped‐Element Passive Components -- 4.4.1 Typical Packages for RF Passive Components -- 4.4.2 Lumped‐Element Resistors -- 4.4.3 Lumped‐Element Capacitors -- 4.4.4 Lumped‐Element Inductors -- 4.5 Miniature Planar Components -- 4.5.1 Spiral Inductors -- 4.5.2 Loop Inductors -- 4.5.3 Interdigitated Capacitors -- 4.5.4 Metal-Insulator-Metal Capacitor -- References -- Chapter 5 S‐Parameters -- 5.1 Introduction -- 5.2 S‐Parameter Definitions -- 5.3 Signal Flow Graphs -- 5.4 Mason's Non‐touching Loop Rule -- 5.5 Reflection Coefficient of a Two‐Port Network -- 5.6 Power Gains of Two‐Port Networks -- 5.7 Stability -- 5.8 Supplementary Problems -- {5.A.1} Transmission Parameters (ABCD Parameters) -- {5.A.2} Admittance Parameters (Y‐Parameters) -- {5.A.3} Impedance Parameters (Z‐Parameters) -- References -- Chapter 6 Microwave Ferrites -- 6.1 Introduction -- 6.2 Basic Properties of Ferrite Materials -- 6.2.1 Ferrite Materials -- 6.2.2 Precession in Ferrite Materials -- 6.2.3 Permeability Tensor -- 6.2.4 Faraday Rotation -- 6.3 Ferrites in Metallic Waveguide -- 6.3.1 Resonance Isolator -- 6.3.2 Field Displacement Isolator -- 6.3.3 Waveguide Circulator -- 6.4 Ferrites in Planar Circuits -- 6.4.1 Planar Circulators -- 6.4.2 Edge‐Guided‐Mode Propagation -- 6.4.3 Edge‐Guided‐Mode Isolator -- 6.4.4 Phase Shifters -- 6.5 Self‐Biased Ferrites -- 6.6 Supplementary Problems -- References -- Chapter 7 Measurements -- 7.1 Introduction -- 7.2 RF and Microwave Connectors -- 7.2.1 Maintenance of Connectors -- 7.2.2 Connecting to Planar Circuits.
7.3 Microwave Vector Network Analyzers -- 7.3.1 Description and Configuration -- 7.3.2 Error Models Representing a VNA -- 7.3.3 Calibration of a VNA -- 7.4 On‐Wafer Measurements -- 7.5 Summary -- References -- Chapter 8 RF Filters -- 8.1 Introduction -- 8.2 Review of Filter Responses -- 8.3 Filter Parameters -- 8.4 Design Strategy for RF and Microwave Filters -- 8.5 Multi‐Element Low‐Pass Filter -- 8.6 Practical Filter Responses -- 8.7 Butterworth (or Maximally Flat) Response -- 8.7.1 Butterworth Low‐Pass Filter -- 8.7.2 Butterworth High‐Pass Filter -- 8.7.3 Butterworth Band‐Pass Filter -- 8.8 Chebyshev (Equal Ripple) Response -- 8.9 Microstrip Low‐Pass Filter, Using Stepped Impedances -- 8.10 Microstrip Low‐Pass Filter, Using Stubs -- 8.11 Microstrip Edge‐Coupled Band‐Pass Filters -- 8.12 Microstrip End‐Coupled Band‐Pass Filters -- 8.13 Practical Points Associated with Filter Design -- 8.14 Summary -- 8.15 Supplementary Problems -- References -- Chapter 9 Microwave Small‐Signal Amplifiers -- 9.1 Introduction -- 9.2 Conditions for Matching -- 9.3 Distributed (Microstrip) Matching Networks -- 9.4 DC Biasing Circuits -- 9.5 Microwave Transistor Packages -- 9.6 Typical Hybrid Amplifier -- 9.7 DC Finger Breaks -- 9.8 Constant Gain Circles -- 9.9 Stability Circles -- 9.10 Noise Circles -- 9.11 Low‐Noise Amplifier Design -- 9.12 Simultaneous Conjugate Match -- 9.13 Broadband Matching -- 9.14 Summary -- 9.15 Supplementary Problems -- References -- Chapter 10 Switches and Phase Shifters -- 10.1 Introduction -- 10.2 Switches -- 10.2.1 PIN Diodes -- 10.2.2 Field Effect Transistors -- 10.2.3 Microelectromechanical Systems -- 10.2.4 Inline Phase Change Switch Devices -- 10.3 Digital Phase Shifters -- 10.3.1 Switched‐Path Phase Shifter -- 10.3.2 Loaded‐Line Phase Shifter -- 10.3.3 Reflection‐Type Phase Shifter -- 10.3.4 Schiffman 90° Phase Shifter.
10.3.5 Single‐Switch Phase Shifter -- 10.4 Supplementary Problems -- References -- Chapter 11 Oscillators -- 11.1 Introduction -- 11.2 Criteria for Oscillation in a Feedback Circuit -- 11.3 RF (Transistor) Oscillators -- 11.3.1 Colpitts Oscillator -- 11.3.2 Hartley Oscillator -- 11.3.3 Clapp-Gouriet Oscillator -- 11.4 Voltage‐Controlled Oscillator -- 11.5 Crystal‐Controlled Oscillators -- 11.5.1 Crystals -- 11.5.2 Crystal‐Controlled Oscillators -- 11.6 Frequency Synthesizers -- 11.6.1 The Phase‐Locked Loop -- 11.6.1.1 Principle of a Phase‐Locked Loop -- 11.6.1.2 Main Components of a Phase‐Locked Loop -- 11.6.1.3 Gain of Phase‐Locked Loop -- 11.6.1.4 Transient Analysis of a Phase‐Locked Loop -- 11.6.2 Indirect Frequency Synthesizer Circuits -- 11.7 Microwave Oscillators -- 11.7.1 Dielectric Resonator Oscillator -- 11.7.2 Delay‐Line Stabilized Microwave Oscillators -- 11.7.3 Diode Oscillators -- 11.7.3.1 Gunn Diode Oscillator -- 11.7.3.2 IMPATT Diode Oscillator -- 11.8 Oscillator Noise -- 11.9 Measurement of Oscillator Noise -- 11.10 Supplementary Problems -- References -- Chapter 12 RF and Microwave Antennas -- 12.1 Introduction -- 12.2 Antenna Parameters -- 12.3 Spherical Polar Coordinates -- 12.4 Radiation from a Hertzian Dipole -- 12.4.1 Basic Principles -- 12.4.2 Gain of a Hertzian Dipole -- 12.5 Radiation from a Half‐Wave Dipole -- 12.5.1 Basic Principles -- 12.5.2 Gain of a Half‐Wave Dipole -- 12.5.3 Summary of the Properties of a Half‐Wave Dipole -- 12.6 Antenna Arrays -- 12.7 Mutual Impedance -- 12.8 Arrays Containing Parasitic Elements -- 12.9 Yagi-Uda Antenna -- 12.10 Log‐Periodic Array -- 12.11 Loop Antenna -- 12.12 Planar Antennas -- 12.12.1 Linearly Polarized A linearly polarized antenna is one where the direction of the radiated electric field remains fixed as the wave propagates. Patch Antennas.
12.12.2 Circularly Polarized Planar Antennas.
Record Nr. UNINA-9910829851603321
Free Charles E.  
Hoboken, New Jersey : , : John Wiley & Sons, Inc., , [2022]
Materiale a stampa
Lo trovi qui: Univ. Federico II
Opac: Controlla la disponibilità qui