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E-raamat: RF Systems, Components, and Circuits Handbook, Second Edition

  • Formaat: 510 pages
  • Ilmumisaeg: 31-Jan-2005
  • Kirjastus: Artech House Publishers
  • ISBN-13: 9781596930018
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RF Systems, Components, and Circuits Handbook, Second EditionSuurem pilt
  • Formaat: 510 pages
  • Ilmumisaeg: 31-Jan-2005
  • Kirjastus: Artech House Publishers
  • ISBN-13: 9781596930018
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Radio frequency (RF) engineering has expanded significantly in both basic research and applications, and this edition has been expanded to suit, including new material on global positioning and wireless communication systems. In fact Losee (electrical engineering emeritus, Brigham Young U.) begins with telephone and wireless communication systems and GPS, then continues to radar systems, radio frequency propagation, RF noise and link analysis, modulation techniques, RF amplifiers, oscillators, frequency multipliers, mixers, modulators, demodulators, and block diagrams, advancing to RF components and circuits such as transmission lines and devices, waveguides, antennas, lumped constant components, transformer devices, piezoelectric and ferrimagnetic devices, acoustic devices, semiconductor diodes, bipolar and field-effect transistors, and high-power vacuum tubes. Annotation ©2005 Book News, Inc., Portland, OR (booknews.com)
Preface xvii
PART I RF Systems
1(216)
Telephone Systems
3(18)
Introduction
3(1)
Telephone Lines
4(3)
Open-Wire Lines
4(1)
Twisted-Pair Lines
4(1)
Coaxial Cable
4(1)
Cordless Telephones
5(1)
2.4-GHz Cordless Telephones
6(1)
5.8-GHz Digital Spread Spectrum (DSS) Cordless Telephones
6(1)
Telephone Relay Systems
7(5)
Microwave Relay Systems
7(1)
Fiber Optics Cable Telephone Relay Systems
8(2)
Submarine Cable Relay Systems
10(1)
Communication Satellite Relay Systems
11(1)
Cellular Telephone Systems
12(7)
Introduction to Cellular Telephones
12(1)
The Concept of Spatial Frequency Reuse
13(1)
Propagation Characteristics of Cellular Telephone Systems
14(1)
Types of Cellular Telephone Systems
14(4)
How a Cellular Telephone Call Is Made
18(1)
Modern Commercially Available Cellular Telephone Systems
19(2)
References
19(2)
Wireless Communication Systems
21(12)
Introduction
21(1)
Background Information
21(2)
Units and Conversion Information
21(1)
Frequency Bands for Communication Systems
22(1)
The Use of Decibels
22(1)
Frequency Allocation and FCC Regulations
23(1)
Types of Communication Services as Defined by the ITU
24(5)
Aeronautical Mobile Service
24(1)
Aeronautical Mobile Satellite Service
25(1)
Amateur Service
25(1)
Broadcasting Service
26(1)
Broadcasting Satellite Service
27(1)
Citizen Band Radio
27(1)
VHF and UHF FM Business and Personal Two-Way Radio
28(1)
Pager Systems
28(1)
Mobile Service
29(1)
Remote Control Systems
29(1)
WLANs, IEEE 802.11 and Bluetooth
29(4)
WLANs
29(1)
IEEE 802.11 Standard
30(1)
IEEE 802.11b Standard
30(1)
IEEE 802.11g Standard
31(1)
Bluetooth
31(1)
References
31(2)
Radionavigation and Global Positioning Systems (GPS)
33(20)
Older Radionavigation Systems
33(7)
Omega System
33(1)
Loran System
34(1)
Radio Beacons and Airborne Direction Finders
35(1)
VOR Systems
36(1)
Distance-Measuring Equipment (DME)
37(1)
Instrument Landing System (ILS)
37(1)
Tactical Air Navigation
38(1)
Microwave Landing System
39(1)
Air Traffic Control Radar Beacon System
39(1)
Transit System
39(1)
GPS Navigation System
40(13)
System Architecture
40(10)
Applications for GPS
50(1)
References
51(2)
Radar Systems
53(30)
Basic Radar Concepts
53(1)
Radar Frequencies
54(1)
Types of Radars Based on Frequency
54(3)
MF Radar (0.3--3.0 MHz)
54(1)
HF Radar (3.0--30 MHz)
55(1)
VHF Radar (30--300 MHz)
55(1)
UHF Radar (300--1,000 MHz)
55(1)
L-Band Radar (1.0--2.0 GHz)
55(1)
S-Band Radar (2.0--4.0 GHz)
56(1)
C-Band Radar (4.0--8.0 GHz)
56(1)
X-Band Radar (8.0--12.0 GHz)
56(1)
KU-Band Radar (12.0--18.0 GHz)
56(1)
K-Band Radar (18.0--27.0 GHz)
56(1)
KaBand Radar (26.5--40.0 GHz)
57(1)
V-Band Radar (40.0--75.0 GHz)
57(1)
W-Band Radar (75--110 GHz)
57(1)
Millimeter-Wave Radar (110--300 GHz)
57(1)
Types of Radar
57(6)
Surveillance Radars
57(1)
CW Speed Measurement Radar
58(1)
Airborne Weather-Avoidance Radar
58(1)
Radar Altimeters
59(1)
Airborne Doppler Navigation Radar
59(1)
Ship-Based Search and Surveillance Radar
60(1)
Shore-Based Search and Surveillance Radar
60(1)
Space Applications of Radar
60(1)
Ground-Based Instrumentation Radars for Locating and Tracking Missiles and Satellites
60(1)
Airborne Military Multiple Function Radars
61(1)
Airborne Terrain-Following Radar
61(1)
Airborne Side-Looking Radar
61(1)
Ground-Based Military Radar for Locating and Tracking Aircraft and Missiles
62(1)
Ground-Based Military Radars for Ground-Based Targets
62(1)
Ship-Based Military Radar
62(1)
ICBM Defense Radars
62(1)
Radar Measurement
63(11)
Radar Cross-Section of Targets
63(2)
Radar Clutter
65(3)
Range Measurements
68(2)
Velocity Measurement Using CW Radar
70(2)
Velocity Measurements Using FMCW Radar
72(1)
Velocity Measurements Using a Pulse-Type Radar
72(1)
Angle Measurements for Radars
73(1)
Moving-Target Indicator (MTI) and Pulse Doppler Radars
74(6)
MTI Radar Types
74(2)
Signal Processing for MTI Radars
76(3)
MTI from a Moving Platform
79(1)
Tracking Radars
80(3)
Monopulse Tracking Radars
80(1)
Tracking in Range Using Sequential Gating
81(1)
References
82(1)
Radio Frequency Propagation
83(20)
Antennas
83(2)
Transmit Antennas
83(1)
Receive Antenna Gain and Capture Area
84(1)
Electromagnetic Waves, Fields, and Power Density
85(1)
RF Electrical Field Waveforms and Vector Addition
86(1)
Free-Space Path Loss
87(1)
Excess Path Loss and Atmospheric Attenuation
87(2)
Atmospheric Absorption
87(1)
Attenuation Produced by Rain, Snow, and Fog
88(1)
Atmospheric Refraction
89(1)
Diffraction of Radio Waves
90(2)
Multipath
92(1)
Ionospheric Propagation
93(2)
Ground-Wave Propagation
95(1)
Scatter Propagation
96(1)
Fiber Optic Cable Propagation
97(1)
Radar Cross-Section of Targets
97(2)
Equations for Calculating Propagation Performance for Communication Systems
99(1)
Example 1: HF Ionospheric Reflection Communication System
99(1)
Example 2: VHF Base Station to Mobile Unit Communication System
100(1)
Example 3: Microwave Uplink to Satellite Relay Located at Geostationary Orbit
100(1)
Equations for Calculating Propagation Performance for Radar Systems
100(3)
Example 4: L-Band Aircraft Surveillance Radar
101(1)
Example 5: X-Band Airborne Multiple-Function Radar
102(1)
References
102(1)
RF Noise and Link Analysis
103(18)
Concepts of RF Noise and Signal-to-Noise Ratio
103(1)
Noise Power, Noise Temperature, and Noise Figure
104(2)
Multiple-Stage Systems with Noise
106(1)
Types of Noise
107(5)
Atmospheric Noise
107(1)
Galactic Noise
108(2)
Solar Noise
110(1)
Ground Noise
111(1)
Man-Made Noise and Interference
111(1)
Signal-to-Noise Improvement by Use of Integration
112(1)
Signal-to-Noise Ratio
113(2)
Communication System Link Analysis
115(1)
Radar System Link Analysis
116(1)
Performance Calculations for Radar Systems with Electronic Countermeasures
117(4)
References
119(2)
Modulation Techniques
121(28)
Pulsed Continuous-Wave Signals
121(1)
Conventional Amplitude Modulation
122(1)
Double Sideband Suppressed Carrier Modulation
123(2)
Vestigial Sideband Modulation
125(1)
Single-Sideband Modulation
125(1)
Standard Frequency Modulation
126(3)
Modulation for Telemetry
129(1)
Combination Communication and Range-Measurement Systems
130(1)
Modulation for Radar
130(4)
Pulsed CW Modulation
130(2)
High-Power Impulse Generators and Ultra-Wideband, High-Power Microwave Generators
132(1)
Chirp Pulse Modulation
133(1)
Phase Code Modulated Pulse Modulation
133(1)
Continuous-Wave Modulation
134(1)
Frequency-Modulated CW Modulation
134(1)
Single-Channel Transmitter System
134(2)
Frequency Division Multiplex Transmitter System
136(1)
Sample Circuits and Analog-to-Digital Converter Concepts
137(1)
Time Division Multiplex Transmitter System with Pulse Code Modulation
137(2)
Two-State Modulation Types for Binary Signals
139(2)
On-Off or Two-State Amplitude Keying
139(1)
Frequency Shift Keying
140(1)
Binary Phase-Shift Keying
140(1)
Four-State and Eight-State Phase-Shift Keying
141(1)
Sixteen Phase-State Keying (16-PSK)
141(1)
Sixteen Amplitude-Phase Keying
142(1)
Direct Sequence Spread Spectrum Modulation
142(7)
Pseudorandom Noise (PN) Generators
142(2)
Direct Sequence Spread Spectrum Systems
144(3)
Applications for Direct Sequence Spread Spectrum
147(1)
References
148(1)
Selected Bibliography
148(1)
RF Amplifiers, Oscillators, Frequency Multipliers, and Mixers
149(28)
Amplifiers
149(14)
Front-End Low-Noise RF Amplifiers for Receivers
149(6)
IF Amplifiers
155(2)
Audio and Other LF Amplifiers
157(1)
Transmitter RF Amplifier Chains
157(1)
Transmitter RF Power Amplifiers for Communication Systems
158(3)
RF Power Amplifiers and Oscillators for Radars, Navigation, and Electronic Countermeasure Applications
161(2)
Oscillators and Frequency Synthesizers
163(3)
Transistor Feedback Oscillators
163(2)
Negative Resistance Two-Terminal Oscillators
165(1)
Frequency Synthesizers
165(1)
Frequency Multipliers
166(3)
Varactor Diode Frequency Multipliers
166(1)
Step-Recovery Diode Frequency Multipliers
167(1)
Transistor Multipliers
168(1)
Mixers
169(8)
Diode Mixers
169(5)
Transistor Mixers
174(2)
References
176(1)
Selected Bibliography
176(1)
Modulators and Demodulators
177(24)
Modulators
177(14)
Modulators for Conventional Amplitude Modulation
177(2)
Modulators for Double-Sideband Modulation
179(2)
Vestigial-Sideband Modulators
181(1)
Modulators for Single-Sideband Modulation
181(3)
Modulators for Frequency-Division Multiplex
184(1)
Modulators for Standard Frequency Modulation
184(3)
Modulators for Frequency-Shift Keying
187(1)
Modulators for Phase-Shift Keying
187(3)
Modulators for Pulse Code Modulation Time-Division Multiplex Modulation
190(1)
Time-Division Multiple Access
191(1)
Demodulators or Detectors
191(10)
Amplitude Modulation Detectors
192(1)
Product Detectors
192(2)
Frequency Modulation Detector Concepts
194(3)
Phase Detectors
197(1)
References
198(3)
Example Communication System Block Diagrams
201(16)
HF Communication System Using Single-Sideband Modulation
201(2)
VHF or UHF Ground-to-Air Communication System Using Either Amplitude Modulation or Narrowband FM
203(2)
Frequency Modulation Broadcast Systems
205(3)
Microwave Relay Systems
208(3)
Satellite Relay Communication Systems
211(4)
Satellite Relay Earth Stations
215(2)
References
216(1)
PART II RF Components and Circuits
217(248)
Transmission Lines and Transmission Line Devices
219(40)
Two-Wire Transmission Lines
219(1)
Coaxial Transmission Lines
220(3)
Coaxial Cable Connectors
223(1)
Microstrip Transmission Lines
224(1)
Stripline Transmission Lines
225(2)
Characteristics of Transmission Lines
227(3)
Wave Velocity on Transmission Lines
227(1)
Reflection Coefficients
227(1)
Standing-Wave Ratio
228(2)
The Smith Chart
230(6)
Impedance and Admittance Coordinates
230(2)
Voltage Standing-Wave Ratio Circles
232(1)
Reflection Coefficients
232(1)
Examples Using the Smith Chart
232(4)
Impedance Matching Using the Smith Chart
236(6)
Impedance Matching with a Quarter-Wave Transformer
236(4)
Impedance Matching with a Short-Circuited Stub
240(2)
Coaxial Terminations
242(1)
Coaxial Directional Couplers
242(1)
Baluns
243(1)
Two-Wire Transmission Line Impedance Transformer
244(1)
Stripline and Microstrip Circuits
245(7)
Shunt Stub DC Returns
245(1)
Branch Line 90-Degree Hybrid Couplers
245(1)
Stripline or Microstrip Rat Race Hybrid Coupler
246(1)
Split Inline Hybrid Dividers and Combiners
247(1)
Quarter-Wave Coupled-Line Directional Couplers
248(1)
90-Degree Coupled-Line Hybrid Coupler
249(1)
Stripline Lowpass Filters
249(1)
Stripline Highpass Filters
250(1)
Stripline Bandpass Filters
251(1)
Ferrite Circulators and Isolators
252(2)
Coaxial Electromechanical Switches
254(2)
PIN Diode Switches
256(1)
Sparkgap Switches for Lightning Protection
257(2)
References
257(1)
Selected Bibliography
257(2)
Waveguides and Waveguide-Related Components
259(28)
Introduction to Waveguides
259(1)
Rectangular Waveguides
260(6)
Higher-Order Modes in Rectangular Waveguides
266(2)
Launching the TE10 Mode Using a Coaxial Line Input
268(1)
Characteristic Wave Impedance for Waveguides
268(2)
Other Types of Waveguides
270(1)
Ridged Waveguides
270(1)
Circular Waveguides
270(1)
Waveguide Hardware
271(2)
Waveguide Flanges
271(1)
Rotary Joints
272(1)
Tapered Transition Sections of Waveguides
272(1)
Flexible Waveguides
272(1)
Waveguide Accessories
273(1)
Waveguide Hybrid Junctions
273(2)
Waveguide Impedance Matching
275(1)
Waveguide Resistive Loads and Attenuators
276(1)
Waveguide Directional Couplers
276(1)
Waveguide Ferrite Isolators, Circulators, and Switches
277(2)
Waveguide Detectors and Mixers
279(1)
Gas-Tube Switches
280(1)
Duplexers
280(3)
Cavity Resonators
283(4)
References
285(1)
Selected Bibliography
285(2)
Antennas
287(54)
Monopole Antennas
289(3)
Thin-Wire Monopole Antennas
289(1)
Wideband Monopoles
290(1)
Impedance of Monopole Antennas
290(1)
Large-Size Monopole Antennas
291(1)
Electrically Small Monopole Antennas
291(1)
Dipole Antennas
292(7)
Thin-Wire Dipole Antennas
292(2)
Other Types of Dipole Antennas
294(1)
Dipole Impedance
294(2)
Dipole Current Distribution and Antenna Patterns for Different L/λ Ratios
296(1)
Turnstile Antennas
297(2)
Yagi-Uda Antennas
299(2)
Sleeve Antennas
301(1)
Sleeve Monopoles
301(1)
Sleeve Dipoles
302(1)
Loop Antennas
302(2)
Air-Core Loop Antennas
302(2)
Ferrite-Core Loop Antennas
304(1)
Helical Antennas
304(2)
Spiral Antennas
306(2)
Equiangular Spiral Antennas
306(1)
Archimedean Spiral Antennas
307(1)
Conical Spiral Antennas
308(1)
Log-Periodic Antennas
308(5)
Log-Periodic Dipole Array
308(3)
Trapezoidal-Toothed Log-Periodic Antennas
311(2)
Triangular-Toothed Log-Periodic Antennas
313(1)
Slot Antennas
313(5)
Open-Slot Antennas
313(2)
Cavity-Backed Rectangular-Slot Antennas
315(1)
Waveguide-Fed Slot Antennas
315(3)
Notch Antennas
318(1)
Horn Antennas
318(2)
Lens Antennas
320(2)
Dielectric Lens Antenna
321(1)
Luneburg Lens Antenna
321(1)
Metallic-Plate Lens Antenna
322(1)
Antenna Arrays
322(4)
End-Fire Line Antenna Arrays
322(2)
Broadside Line Antenna Arrays
324(2)
Planar Arrays
326(1)
Scanning Methods
326(4)
Mechanically Scanned Arrays
326(3)
Arrays with Space Feeds
329(1)
Flat-Plate Reflector Type Antennas
330(1)
Half-Wave Dipole Antennas with Reflectors
330(1)
Corner Reflector Antennas
330(1)
Parabolic Reflector Antennas
330(3)
Patch Antennas
333(8)
Introduction
333(1)
Types of Patch Antennas
334(1)
Antenna Feeds
335(1)
Broadbanding
336(1)
SSFIP Antennas
336(1)
Dual Polarized and Circularly Polarized Patch Antennas
337(1)
Patch Antenna Arrays
338(1)
References
339(2)
Lumped Constant Components and Circuits
341(28)
Conductors and Skin Effect
341(1)
RF Resistors
342(1)
Inductors and Inductive Reactance
342(4)
RF Chokes
346(1)
Capacitors and Capacitive Reactance
346(3)
Series Resonant RLC Circuits
349(1)
Parallel Resonant RLC Circuits
350(2)
Complex Resonant Circuits
352(3)
The Use of the Smith Chart for Circuit Analysis
355(2)
S-Parameters
357(1)
Impedance Matching Using LC Circuits
358(2)
Impedance-Matching Design Using the Smith Chart
360(5)
LC Filters
365(4)
References
368(1)
RF Transformer Devices and Circuits
369(14)
Conventional Transformers
369(2)
Magnetic Core Material for RF Transformers
371(2)
Tuned Transformers
373(1)
High-Frequency Wideband Conventional RF Transformers
374(4)
Transmission-Line Transformers
378(3)
Power Combiners and Splitters
381(2)
References
382(1)
Piezoelectric, Ferrimagnetic, and Acoustic Devices and Circuits
383(20)
Quartz Crystal Resonators and Oscillators
383(3)
Monolithic Crystal Filters
386(1)
Ceramic Filters
387(1)
Dielectric Resonant Oscillators
388(3)
Dielectric Resonator Description and Parameters
388(2)
Coupling Between a Dielectric Resonator and a Microstrip Line
390(1)
Mechanical and Electrical Tuning of Dielectric Resonators
391(1)
Examples of Dielectrically Stabilized Oscillators
391(1)
YIG Resonators and Filters
391(2)
Ferrimagnetic Resonance in Yttrium Iron Garnet Crystals
391(2)
YIG Bandpass Filters
393(1)
YIG-Tuned Oscillators
393(1)
Surface Acoustic Wave Delay Lines
393(6)
Nondispersive Delay Lines
393(2)
Tapped Delay Lines
395(1)
Dispersive Delay Lines
396(3)
Surface Acoustic Wave Delay Line Oscillators
399(1)
Bulk Acoustic Wave Delay Lines
400(3)
References
402(1)
Semiconductor Diodes and Their Circuits
403(12)
Semiconductor Materials
403(1)
``Ordinary'' Junction Diodes
403(1)
Zener Diodes
404(1)
Schottky-Barrier Diodes
404(1)
PIN Diodes
405(1)
Varactor Diodes
406(1)
Step-Recovery Diodes
407(1)
Microwave Tunnel Diodes and Circuits
408(1)
Microwave Gunn Diodes and Circuits
408(2)
Microwave IMPATT Diodes
410(2)
Semiconductor IR Laser Diodes
412(1)
Light-Emitting Diodes
413(1)
IR Photodiodes
413(2)
References
414(1)
Bipolar and Field-Effect Transistors and Their Circuits
415(30)
Bipolar Junction Transistors
415(2)
BJT Amplifier Configurations
417(9)
Common-Emitter Amplifier
417(5)
Common-Base Amplifier
422(2)
Common-Collector Amplifier
424(2)
Field Effect Transistors and Circuits
426(5)
Junction Field-Effect Transistors
426(2)
Metal-Semiconductor Field-Effect Transistors
428(1)
Metal-Oxide Semiconductor Field Effect Transistors
429(2)
Comparison of FET and BJT Amplifiers
431(2)
High Electron Mobility Transistors and Heterojunction Bipolar Transistors
433(1)
High Electron Mobility Transistors
433(1)
Heterojunction Bipolar Transistors
434(1)
DC Bias Circuits for BJT Amplifiers
434(2)
Bias Circuits for FET Amplifiers
436(1)
Stability with BJT and FET Amplifiers
436(1)
Impedance Matching
437(1)
Design Methods with S-Parameters
438(2)
Manufacturers' Data Sheets For Transistors
440(5)
References
443(2)
High-Power Vacuum Tube Amplifiers and Oscillators
445(20)
Grid Tubes
445(6)
Triode, Tetrode, and Pentode Vacuum Tubes
445(2)
Grid-Type Vacuum Tube Amplifiers and Modulated Amplifiers
447(3)
The Use of Cavities as Resonators for High-Power, High-Frequency Triodes and Tetrodes
450(1)
Microwave Tubes and Circuits
451(14)
Introduction to Microwave Tubes
451(2)
Multiple-Cavity Klystron Amplifiers
453(2)
Helix-Type Traveling-Wave Tube Amplifiers
455(3)
Coupled-Cavity Traveling-Wave Tube Amplifiers
458(1)
Conventional Magnetrons
458(1)
Coaxial Cavity Magnetron
459(2)
Amplitrons
461(1)
Gyrotron Oscillators and Amplifiers
462(1)
Circuit Configurations for Microwave Tubes
462(2)
References
464(1)
About the Author 465(2)
Index 467


Ferril Losee has more than 40 years of electrical engineering experience, both as an industry professional and a university instructor. He holds a B.S. and M.S. in electrical engineering from the University of Utah and the University of Southern California, respectively.
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