| With note |
Contents:<br/>PREFACE<br/>Chapter 0<br/>INTRODUCTION<br/>0-1 Microwave Frequencies<br/>0-2 Microwave Devices <br/>0-3 Microwave Systems <br/>0-4 Microwave Units of Measure <br/>Chapter 1<br/>INTERACTIONS BETWEEN ELECTRONS AND FIELDS<br/>1-0 Introduction <br/>1-1 Electron Motion in an Electric Field <br/>1-2 Electron Motion in a Magnetic Field <br/>1-3 Electron Motion in an Electromagnetic Field <br/>Suggested Readings <br/>Problems <br/>Chapter 2<br/>ELECTROMAGNETIC PLANE WAVES<br/>2-0 Introduction 16<br/>2-1 Electric and Magnetic Wave Equations <br/>2-2 Poynting Theorem <br/>2-3 Uniform Plane Waves and Reflection <br/>2-3-1 Uniform Plane Waves, <br/>2-3-2 Boundary Conditions, <br/>2-3-3 Uniform Plane-Wave Reflection, <br/>2-4 Plane-Wave Propagation in Free Space and Lossless<br/>Dielectric <br/>2-4-1 Plane-Wave Propagation in Free Space, <br/>2-4-2 Plane-Wave Propagation in Lossless Dielectric, <br/>2-5 Plane-Wave Propagation in Lossy Media <br/>2-5-1 Plane Wave in Good Conductor, <br/>2-5-2 Plane Wave in Poor Conductor, <br/>2-5-3 Plane Wave in Lossy Dielectric, <br/>2-6 Plane-Wave Propagation in Metallic-Film Coating on Plastic<br/>Substrate <br/>2-6-1 Surface Resistance of Metallic Films, <br/>2-6-2 Optical Constants of Plastic Substrates and Metallic Films, <br/>2-6-3 Microwave Radiation Attenuation of Metallic-Film Coating on<br/>Plastic Substrate, <br/>2-6-4 Light Transmittance of Metallic-Film Coating on Plastic Substrate. <br/>2-6-5 Plane Wave in Gold-Film Coating on Plastic Glass, <br/>2-6-6 Plane Wave in Silver-Film or Copper-Film Coating on Plastic<br/>Substrate,<br/>References<br/>Suggested Readings<br/>Problems <br/>Chapter 3<br/>MICROWAVE TRANSMISSION LINES<br/>3-0 Introduction <br/>3-1 Transmission-Line Equations and Solutions <br/>3-1-1 Transmission-Line Equations. <br/>3-1-2 Solutions of Transmission-Line Equations, <br/>3-2 Reflection Coefficient and Transmission Coefficient <br/>3-2-1 Reflection Coefficient, <br/>3-2-2 Transmission Coefficient, <br/>3-3 Standing Wave and Standing-Wave Ratio <br/>3-3-1 Standing Wave, <br/>3-3-2 Standing-Wave Ratio, <br/>3-4 Line Impedance and Admittance <br/>3-5 Smith Chart <br/>3-6 Impedance Matching<br/>3-6-1 Single-Stub Matching, <br/>3-6-2 Double-Stub Matching,<br/>3-7 Microwave Coaxial Connectors<br/>References<br/>Suggested Readings<br/>Problems <br/>Chapter 4<br/>MICROWAVE WAVEGUIDES AND COMPONENTS<br/>4-0 Introduction <br/>4-1 Rectangular Wave guides <br/>4-1-1 Solutions of Wave Equations in Rectangular Coordinates, <br/>4-1-2 TE Modes in Rectangular Wave guides, <br/>4-1-3 TM Modes in Rectangular Waveguides,<br/>4-1-4 Power Transmission in Rectangular Waveguides, <br/>4-1-5 Power Losses in Rectangular Waveguides, <br/>4-1-6 Excitations of Modes in Rectangular Waveguides, <br/>4-1 -7 Characteristics of Standard Rectangular Waveguides, <br/>4-2 Circular Waveguides <br/>4-2-1 Solutions of Wave Equations in Cylindrical Coordinates, <br/>4-2-2 TE Modes in Circular Waveguides, <br/>4-2-3 TM Modes in Circular Waveguides, <br/>4-2-4 TEM Modes in Circular Waveguides, <br/>4-2-5 Power Transmission in Circular Waveguides or Coaxial<br/>Lines, <br/>4-2-6 Power Losses in Circular Waveguides or Coaxial Lines,<br/>4-2-7 Excitations of Modes in Circular Waveguides, <br/>4-2-8 Characteristics of Standard Circular Waveguides, <br/>4-3 Microwave Cavities <br/>4-3-1 Rectangular-Cavity Resonator, <br/>4-3-2 Circular-Cavity Resonator and Semicircular-Cavity Resonator, <br/>4-3-3 Q Factor of a Cavity Resonator, <br/>4-4 Microwave Hybrid Circuits <br/>4-4-1 Waveguide Tees, <br/>4-4-2 Magic Tees (Hybrid Trees), <br/>4-4-3 Hybrid Rings (Rat-Race Circuits), <br/>4-4-4 Waveguide Corners, Bends, and Twists<br/>4-5 Directional Couplers<br/>4-5-1 Two-Hole Directional Couplers, <br/>4-5-2 S Matrix of a Directional Coupler<br/>4-5-3 Hybrid Couplers, <br/>4-6 Circulators and Isolators <br/>4-6-1 Microwave Circulators, <br/>4-6-2 Microwave Isolators, <br/>References <br/>Suggested Readings<br/>Problems<br/>Chapter 5<br/>MICROWAVE TRANSISTORS AND TUNNEL DIODES<br/>5-0 Introduction <br/>5-1 Microwave Bipolar Transistors <br/>5-1-1 Physical Structures,<br/>5-1-2 Bipolar Transistor Configurations, <br/>5-1-3 Principles of Operation, <br/>5-1-4 Amplification Phenomena, <br/>5-1-5 Power-Frequency Limitations, <br/>5-2 Heterojunction Bipolar Transistors (HBTs) <br/>5-2-1 Physical Structures, <br/>5-2-2 Operational Mechanism, <br/>5-2-3 Electronic Applications, <br/>5-3 Microwave Tunnel Diodes,<br/>5-3-1 Principles of Operation, <br/>5-3-2 Microwave Characteristics, <br/>References <br/>Suggested Readings <br/>Problems <br/>MICROWAVE FIELD-EFFECT TRANSISTORS<br/>6-0 Introduction <br/>6-1 Junction Field-Effect Transistors (JFETs) <br/>6-1-1 Physical Structure, <br/>6-1-2 Principles of Operation, <br/>6-1-3 Current-Voltage (1-V) Characteristics, <br/>6-2 Metal-Semiconductor Field-Effect Transistors<br/>(MESFETs) <br/>6-2-1 Physical Structures, <br/>6-2-2 Principles of Operation,<br/>6-2-3 Small-Signal Equivalent Circuit, <br/>6-2-4 Drain Current h <br/>6-2-5 Cutoff Frequency fco and Maximum Oscillation Frequency<br/>/max, <br/>6-3 High Electron Mobility Transistors (HEMTs) <br/>6-3-1 Physical Structure, <br/>6-3-2 Operational Mechanism, <br/>6-3-3 Performance Characteristics, <br/>6-3-4 Electronic Applications, <br/>6-4 Metal-Oxide-Semiconductor Field-Effect Transistors<br/>(MOSFETs) <br/>6-4-1 Physical Structures, <br/>6-4-2 Electronic Mechanism, <br/>6-4-3 Modes of Operation, <br/>6-4-4 Drain Current and Transconductance,<br/>6-4-5 Maximum Operating Frequency, <br/>6-4-6 Electronic Applications, <br/>6-5 MOS Transistors and Memory Devices <br/>6-5-1 NMOS Devices, <br/>6-5-2 CMOS Devices, <br/>6-5-3 Memory Devices, <br/>6-6 Charge-Coupled Devices (CCDs) <br/>6-6-1 Operational Mechanism, <br/>6-6-2 Surface-Channel Charge-Coupled Devices (SCCDs),<br/>6-6-3 Dynamic Characteristics<br/>7-6 CdTe Diodes <br/>7-7 Microwave Generation and Amplification <br/>7-7-1 Microwave Generation, <br/>7-7-2 Microwave Amplification, <br/>References <br/>Suggested Readings <br/>Problems<br/>Chapter 8 AVALANCHE TRANSIT-TIME DEVICES<br/>8-0 Introduction <br/>8-1 Read Diode <br/>8-1-1 Physical Description, <br/>8-1-2 Avalanche Multiplication, <br/>8-1-3 Carrier Current l 0 (t) and External Current J,(t), <br/>8-1-4 Output Power and Quality Factor Q, <br/>8-2 IMPATI Diodes <br/>8-2-1 Physical Structures, <br/>8-2-2 Negative Resistance, <br/>8-2-3 Power Output and Efficiency, <br/>8-3 TRAPATT Diodes <br/>8-3-1 Physical Structures, <br/>8-3-2 Principles of Operation, <br/>8-3-3 Power Output and Efficiency, <br/>8-4 BARITT Diodes <br/>8-4-1 Physical Description, <br/>8-4-2 Principles of Operation, <br/>8-4-3 Microwave Performance, <br/>8-5 Parametric Devices <br/>8-5-1 Physical Structures, <br/>8-5-2 Nonlinear Reactance and Manley-Rowe Power Relations, <br/>8-5-3 Parametric Amplifiers, <br/>8-5-4 Applications, <br/>References <br/>Suggested Readings <br/>Problems <br/>Chapter 9 MICROWAVE LINEAR-BEAM TUBES (0 TYPE) <br/>9-0 Introduction<br/>9-1 Conventional Vacuum Triodes, Tetrodes, and Pentodes<br/>9-1-1 Lead-Inductance and lnterelectrode-Capacitance Effects, <br/>9-1-2 Transit-Angle Effects, <br/>9-1-3 Gain-Bandwidth Product Limitation, <br/>9-2 Klystrons <br/>9-2-1 Reentrant Cavities, <br/>9-2-2 Velocity-Modulation Process, <br/>9-2-3 Bunching Process<br/>9-2-4 Output Power and Beam Loading, <br/>9-2-5 State of the Art, <br/>9-3 Multicavity Klystron Amplifiers <br/>9-3-1 Beam-Current Density, <br/>9-3-2 Output Current and Output Power of Two-Cavity Klystron,<br/>9-3-3 Output Power of Four-Cavity Klystron,<br/>9-4 Reflex Klystrons <br/>9-4-1 Velocity Modulation <br/>9-4-2 Power Output and Efficiency, <br/>9-4-3 Electronic Admittance, <br/>9-5 Helix Traveling-Wave Tubes (TWTs) <br/>9-5-1 Slow-Wave Structures, <br/>9-5-2 Amplification Process, <br/>9-5-3 Convection Current, <br/>9-5-4 Axial Electric Field, <br/>9-5-5 Wave Modes, <br/>9-5-6 Gain Consideration, <br/>9-6 Coupled-Cavity Traveling-Wave Tubes <br/>9-6-1 Physical Description, <br/>9-6-2 Principles of Operation, <br/>9-6-3 Microwave Characteristics, <br/>9-7 High-Power and Gridded-Control Traveling-Wave Tubes <br/>9-7-1 High Efficiency and Collector Voltage Depression, <br/>9-7-2 Normal Depression and Overdepression of Collector Voltage,<br/>9-7-3 Two-Stage Collector Voltage Depression Technique, <br/>9-7-4 Stabilization of Cathode and Collector Voltages, <br/>References <br/>Suggested Readings <br/>Problems <br/>Chapter 10 MICROWAVE CROSSED-FIELD TUBES (M TYPE)<br/>I 0-0 Introduction <br/>I 0-1 Magnetron Oscillators <br/>10-1-1 Cylindrical Magnetron,<br/>10-1-2 Linear Magnetron,<br/>10-1-3 Coaxial Magnetron, <br/>10-1-4 Voltage-Tunable Magnetron, <br/>10-1-5 Inverted Coaxial Magnetron, <br/>10-1-6 Frequency-Agile Coaxial Magnetron, <br/>10-2 Forward-Wave Crossed-Field Amplifier (FWCFA OR<br/>CFA) <br/>10-2-1 Principles of Operation, <br/>10-2-2 Microwave Characteristics <br/>10-3 Backward-Wave Crossed-Field Amplifier (Amplitron) <br/>10-4 Backward-Wave Crossed-Field Oscillator<br/>(Carcinotron)<br/>References <br/>Problems <br/>STRIP LINES<br/>11-0 Introduction <br/>11-1 Microstrip Lines <br/>11-1-1 Characteristic Impedance of Microstrip Lines, <br/>11-1-2 Losses in Microstrip Lines <br/>11-1-3 Quality Factor Q of Microstrip Lines <br/>11-2 Parallel Strip Lines <br/>11-2-1 Distributed Parameters <br/>11-2-2 Characteristic Impedance<br/>11-2-3 Attenuation Losses <br/>l l-3 Coplanar Strip Lines <br/>11-4 Shielded Strip Lines <br/>References <br/>Problems <br/>MONOLITHIC MICROWAVE INTEGRATED CIRCUITS<br/>12-0 Introduction <br/>12-1 Materials <br/>12-1-1 Substrate Materials <br/>12-1-2 Conductor Materials <br/>12-1-3 Dielectric Materials <br/>12-1-4 Resistive Materials <br/>12-2 Monolithic Microwave Integrated-Circuit Growth <br/>12-2-1 MMIC Fabrication Techniques, <br/>12-2-2 Fabrication Example,<br/>12-3 MOSFET Fabrication <br/>12-3-1 MOSFET Formation, <br/>12-3-2 NMOS Growth, <br/>12-3-3 CMOS Development, <br/>12-3-4 Memory Construction<br/>12-4 Thin-Film Formation <br/>12-4-1 Planar Resistor Film <br/>12-4-2 Planar Inductor Film <br/>12-4-3 Planar Capacitor Film <br/>12-5 Hybrid Integrated-Circuit Fabrication <br/>References <br/>Suggested Readings <br/>Problems <br/>APPENDIX A<br/>APPENDIX B<br/>INDEX |