Microwave and RF Design of Wireless Systems,9780471322825

Microwave and RF Design of Wireless Systems

by
Edition: 1st
ISBN13: 9780471322825
ISBN10: 0471322822
Format: Hardcover
Pub. Date: 2000-11-29
Publisher(s): Wiley
  • Free Shipping Icon

    Free Shipping On Orders Over $59

    Free standard shipping on order over $59 to your home address. Marketplace purchases through third-party sellers are excluded from free shipping promotions.

List Price: $318.47

Buy New

Usually Ships in 8 - 10 Business Days.
$303.30
Add to Cart

Rent Textbook

Select for Price
Add to Cart
There was a problem. Please try again later.

Digital

Rent Digital Options
Online:150 Days access
Downloadable:150 Days
$40.80
Online:1825 Days access
Downloadable:Lifetime Access
$92.34
*To support the delivery of the digital material to you, a non-refundable digital delivery fee of $3.99 will be charged on each digital item.
$40.80*
Add to Cart

Used Textbook

We're Sorry
Sold Out

Buy from our Marketplace starting at $69.27

How Marketplace Works:

  • This item is offered by an independent seller and not shipped from our warehouse
  • Item details like edition and cover design may differ from our description; see seller's comments before ordering.
  • Sellers much confirm and ship within two business days; otherwise, the order will be cancelled and refunded.
  • Marketplace purchases cannot be returned to eCampus.com. Contact the seller directly for inquiries; if no response within two days, contact customer service.
  • Additional shipping costs apply to Marketplace purchases. Review shipping costs at checkout.

Summary

Undersztand every aspect of modern wireless system design From the antenna to the baseband level - David Pozar's MICROWAVE AND RF DESIGN OF WIRELESS SYSTEMS offers ther most completer and up-to-date presentation of the operation and design of modern wireless telecommunication systems. Integrating a wide range of topics into one design-oriented framework, the text covers antennas and propagation, noise characterization of systems and components, digital modulation methods, and the design and operation of wireless components such as filters, amplifiers, mixers, and phase-locked loops. This comprehensive approach helps readers understand how the various technologies involved in wireless systems are interrelated. The text builds on a strong foundation of fundamental principles, and offers many practical examples and design problems. You'll learn how to: Design modern wireless telecommunication and data transmission systems. Analyze a complete radio system, from the transmitter through thereceiver front-end. Evaluate factors such as carrier-to-noise ratio, receiver noise figure, intermodulation products, spurious mixer products, image frequencies, dynamic range, Rayleigh fading, bit error rate, and maximum data rate.'Solve real-world, design-oriented problems.

Author Biography

David M. Pozar is the author of Microwave and RF Design of Wireless Systems, published by Wiley.

Table of Contents

Introduction to Wireless Systems
1(29)
Wireless Systems and Markets
2(9)
Classification of Wireless Systems
2(1)
Cellular Telephone Systems
3(2)
Personal Communications Systems
5(1)
Satellite Systems for Wireless Voice and Data
6(1)
Global Positioning Satellite System
7(2)
Wireless Local Area Networks
9(1)
Other Wireless Systems
9(2)
Design and Performance Issues
11(5)
Choice of Operating Frequency
12(1)
Multiple Access and Duplexing
13(1)
Circuit Switching versus Packet Switching
13(1)
Propagation
14(1)
Radiated Power and Safety
15(1)
Other Issues
16(1)
Introduction to Wireless System Components
16(7)
Basic Radio System
17(2)
Antennas
19(1)
Filters
19(2)
Amplifiers
21(1)
Mixers
22(1)
Oscillators
22(1)
Baseband Processing
23(1)
Cellular Telephone Systems and Standards
23(6)
Cellular and the Public Switched Telephone Network
23(1)
AMPS Cellular Telephone System
24(2)
Digital Personal Communications System Standards
26(3)
Transmission Lines and Microwave Networks
29(39)
Transmission Lines
29(12)
Lumped Element Model for a Transmission Line
30(1)
Wave Propagation on a Transmission Line
31(1)
Lossless Transmission Lines
32(1)
Terminated Transmission Lines
33(3)
Special Cases of Terminated Transmission Lines
36(3)
Generator and Load Mismatches
39(2)
The Smith Chart
41(6)
Derivation of the Smith Chart
42(2)
Basic Smith Chart Operations
44(1)
Using The Admittance Smith Chart
45(2)
Microwave Network Analysis
47(8)
Impedance and Admittance Matrices
47(3)
The Scattering Matrix
50(3)
The Transmission (ABCD) Matrix
53(2)
Impedance Matching
55(13)
The Quarter-Wave Transformer
56(2)
Matching Using L-Sections
58(3)
Single-Stub Tuning
61(7)
Noise and Distortion in Microwave Systems
68(43)
Review of Random Processes
69(5)
Probability and Random Variables
69(1)
The Cumulative Distribution Function
69(1)
The Probability Density Function
70(1)
Some Important Probability Density Functions
71(1)
Expected Values
71(1)
Autocorrelation and Power Spectral Density
72(2)
Thermal Noise
74(3)
Noise Voltage and Power
74(3)
Noise in Linear Systems
77(6)
Autocorrelation and Power Spectral Density in Linear Systems
77(1)
Gaussian White Noise through an Ideal Low-pass Filter
78(1)
Gaussian White Noise through an ideal Integrator
79(1)
Mixing of Noise
80(1)
Narrowband Representation of Noise
81(2)
Basic Threshold Detection
83(4)
Probability of Error
84(3)
Noise Temperature and Noise Figure
87(6)
Equivalent Noise Temperature
87(1)
Measurement of Noise Temperature
88(1)
Noise Figure
89(1)
Noise Figure of a Lossy Line
90(1)
Noise Figure of Cascaded Components
91(2)
Noise Figure of Passive Networks
93(5)
Noise Figure of a Passive Two-port Network
94(1)
Application to a Mismatched Lossy Line
95(1)
Application to a Wilkinson Power Divider
96(2)
Dynamic Range and Intermodulation Distortion
98(13)
Gain Compression
99(1)
Intermodulation Distortion
100(1)
Third-Order Intercept Point
101(1)
Dynamic Range
102(2)
Intercept Point of Cascaded Components
104(2)
Passive Intermodulation
106(5)
Antennas and Propagation for Wireless Systems
111(40)
Antenna System Parameters
111(9)
Fields and Power Radiated by an Antenna
112(2)
Far-Field Distance
114(1)
Radiation Intensity
114(1)
Radiation Patterns
115(1)
Directivity
116(1)
Radiation Efficiency
117(1)
Gain
118(1)
Aperture Efficiency
118(1)
Effective Area
118(1)
Antenna Polarization
119(1)
The Friis Equation
120(5)
The Friis Equation
120(1)
Effective Isotropic Radiated Power
121(1)
Impedance Mismatch
122(1)
Polarization Mismatch
123(1)
Equivalent Circuits for Transmit and Receive Antennas
124(1)
Antenna Noise Temperature
125(6)
Background and Brightness Temperature
125(2)
Antenna Noise Temperature
127(2)
G/T
129(2)
Basic Practical Antennas
131(7)
Electrically Small Dipole Antenna
132(2)
Half-Wave Dipole Antenna
134(1)
Monopole Antenna
135(1)
Sleeve Monopole Antenna
136(1)
Electrically Small Loop Antenna
137(1)
Propagation
138(6)
Free-space Propagation
139(1)
Ground Reflections
140(2)
Path Loss for Ground Reflections
142(1)
Realistic Path Loss
142(1)
Attenuation
143(1)
Fading
144(7)
Rayleigh Fading
145(6)
Filters
151(38)
Filter Design by the Insertion Loss Method
152(6)
Characterization by Power Loss Ratio
152(2)
Maximally Flat Low-Pass Filter Prototype
154(3)
Equal-Ripple Low-Pass Filter Prototype
157(1)
Linear Phase Low-Pass Filter Prototype
158(1)
Filter Scaling and Transformation
158(10)
Impedance Scaling
158(1)
Frequency scaling for low-pass filters
159(3)
Low-pass to High-pass Transformation
162(2)
Bandpass and Bandstop Transformation
164(4)
Low-Pass and High-Pass Filters Using Transmission Line Stubs
168(5)
Richard's Transformation
168(1)
Kuroda's Identities
169(4)
Stepped-Impedance Low-Pass Filters
173(16)
Approximate Equivalent Circuits for Short Transmission Line Sections
174(4)
Bandpass Filters Using Transmission Line Resonators
178(1)
Impedance and Admittance Inverters
178(1)
Bandpass Filters Using Quarter-Wave Coupled Quarter-Wave Resonators
179(4)
Bandpass Filters Using Capacitively Coupled Quarter-Wave Resonators
183(6)
Amplifiers
189(36)
FET and Bipolar Transistor Models
190(4)
Field Effect Transistors
190(2)
Bipolar Transistors
192(2)
Two-port Power Gains
194(5)
Definitions of Two-Port Power Gains
194(3)
Special Cases
197(1)
Further Discussion of Two-Port Power Gains
198(1)
Stability
199(6)
Stability Circles
200(2)
Tests for Unconditional Stability
202(3)
Amplifier Design Using S Parameters
205(9)
Design for Maximum Gain
205(2)
Maximum Stable Gain
207(3)
Constant Gain Circles and Design for Specified Gain
210(4)
Low-noise Amplifier Design
214(4)
Power Amplifiers
218(7)
Characteristics of Power Amplifiers and Amplifier Classes
218(1)
Large-Signal Characterization of Transistors
219(2)
Design of Class A Power Amplifiers
221(4)
Mixers
225(25)
Mixer Characteristics
225(5)
Frequency Conversion
225(2)
Image Frequency
227(1)
Conversion Loss
228(1)
Noise Figure
229(1)
Intermodulation Distortion
230(1)
Isolation
230(1)
Diode Mixers
230(9)
Small-Signal Diode Characteristics
231(1)
Single-Ended Mixer
232(1)
Large-Signal Model
233(4)
Switching Model
237(2)
FET Mixers
239(4)
Single-Ended FET Mixer
239(3)
Other FET Mixers
242(1)
Other Mixer Circuits
243(7)
Balanced Mixers
243(2)
Small-Signal Analysis of the Balanced Mixer
245(1)
Image Reject Mixer
246(4)
Transistor Oscillators and Frequency Synthesizers
250(38)
Radio Frequency Oscillators
251(7)
General Analysis
251(1)
Oscillators Using a Common Emitter BJT
252(2)
Oscillators Using a Common Gate FET
254(1)
Practical Considerations
255(1)
Crystal Oscillators
256(2)
Voltage-Controlled Oscillators
258(1)
Microwave Oscillators
258(10)
Negative Resistance Oscillators
259(2)
Transistor Oscillators
261(3)
Dielectric Resonator Oscillators
264(4)
Frequency Synthesis Methods
268(5)
Direct Synthesis
268(1)
Digital Look-up Synthesis
269(2)
Phase-Locked Loops
271(1)
Practical Synthesizer Circuits
272(1)
Fractional-N Phase-Locked Loops
273(1)
Phase-Locked Loop Analysis
273(7)
Phase Detectors
274(1)
Transfer Function for the Voltage-Controlled Oscillator
275(1)
Analysis of Linearized Phase-Locked Loop
275(2)
First-Order Loop
277(1)
Second-Order Loop
278(2)
Oscillator Phase Noise
280(8)
Representation of Phase Noise
281(1)
Leeson's Model for Oscillator Phase Noise
282(3)
Effect of Phase Noise on Receiver Performance
285(3)
Modulation Techniques
288(47)
Analog Modulation
288(15)
Single-Sideband Modulation
289(3)
Double-Sideband Suppressed-Carrier Modulation
292(3)
Double-Sideband Large-Carrier Modulation
295(1)
Envelope Detection of Double-Sideband Modulation
296(2)
Frequency Modulation
298(5)
Binary Digital Modulation
303(6)
Binary Signals
304(1)
Amplitude Shift Keying
304(2)
Frequency Shift Keying
306(1)
Phase Shift Keying
307(2)
Carrier Synchronization
309(1)
Error Probabilities for Binary Modulation
309(11)
PCM Signals and Detectors
310(1)
Synchronous ASK
311(1)
Synchronous PSK
312(1)
Synchronous FSK
313(1)
Envelope Detection of ASK
313(3)
Envelope Detection of FSK
316(1)
Bit Rate and Bandwidth Efficiency
317(1)
Comparison of ASK, FSK, and PSK Systems
318(2)
Effect of Rayleigh Fading on Bit Error Rates
320(4)
Effect of Rayleigh Fading on Coherent PSK
321(1)
Effect of Rayleigh Fading on Noncoherent FSK
322(1)
Comparison of Faded and Nonfaded Error Rates
322(2)
M-ary Digital Modulation
324(11)
Quadrature Phase Shift Keying
325(2)
Probability of Error for QPSK
327(3)
M-ary Phase Shift Keying
330(1)
Quadrature Amplitude Modulation
330(1)
Channel Capacity
331(4)
Receiver Design
335(22)
Receiver Architectures
335(5)
Receiver Requirements
335(2)
Tuned Radio Frequency Receiver
337(1)
Direct Conversion Receiver
337(1)
Superheterodyne Receiver
338(1)
Duplexing
338(2)
Dynamic Range
340(7)
Minimum Detectable Signal
341(2)
Sensitivity
343(1)
Dynamic Range
343(1)
Automatic Gain Control
344(2)
Compression and Third-order Intermodulation
346(1)
Frequency Conversion and Filtering
347(3)
Selection of IF Frequency
347(1)
Filtering
348(1)
Spurious-free Range
348(2)
Examples of Practical Receivers
350(7)
FM Broadcast Receiver
350(1)
Digital Cellular Receiver
351(1)
Millimeter Wave Point-to-Point Radio Receiver
352(3)
Direct-Conversion GSM Receiver
355(2)
APPENDICES 357(6)
A Wireless System Frequency Bands
358(1)
B Useful Mathematical Results
358(1)
C Fourier and Laplace Transforms
359(1)
D The Complementary Error Function
360(1)
E Chebyshev Polynomials
361(1)
F Decibels and Nepers
362(1)
Index 363

An electronic version of this book is available through VitalSource.

This book is viewable on PC, Mac, iPhone, iPad, iPod Touch, and most smartphones.

By purchasing, you will be able to view this book online, as well as download it, for the chosen number of days.

Digital License

You are licensing a digital product for a set duration. Durations are set forth in the product description, with "Lifetime" typically meaning five (5) years of online access and permanent download to a supported device. All licenses are non-transferable.

More details can be found here.

A downloadable version of this book is available through the eCampus Reader or compatible Adobe readers.

Applications are available on iOS, Android, PC, Mac, and Windows Mobile platforms.

Please view the compatibility matrix prior to purchase.