Radiowave Propagation Physics and Applications,9780470542958

Radiowave Propagation Physics and Applications

by ; ;
Edition: 1st
ISBN13: 9780470542958
ISBN10: 0470542950
Format: Hardcover
Pub. Date: 2010-06-01
Publisher(s): Wiley
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Summary

Radiowave Propagation provides an overview of the physical mechanisms governing electromagnetic wave propagation in the Earth's troposphere and ionosphere. With an accessible and student-oriented approach, this textbook explores a wide range of topics in a combination of physical and empirical descriptions. Student-approved by Ohio State University, this source presents current empirical information, helping students to strengthen their electromagnetic physics skills. Both engineers and students will find the balance of physical and empirical models provides the basic physical insight as well as practical means for the computations needed in system design.

Author Biography

Curt A. Levis was director of The Ohio State University ElectroScience Laboratory from 1961 to 1969. He received the Eta Kappa Nu Distinguished Teaching Award in 1978, 1979, and 1980; he also received a Distinguished Teaching Award from The Ohio State University Alumni Association in 1980. Professor Levis is an IEEE Fellow.
Joel T. Johnson is a professor in the Department of Electrical and Computer Engineering and ElectroScience Laboratory at The Ohio State University. His research interests are in the areas of electromagnetics, propagation, and microwave remote sensing. He is an IEEE Fellow and a recipient of the ONR Young Investigator, PECASE, and NSF CAREER awards.
Fernando L. Teixeira is an associate professor in the Department of Electrical and Computer Engineering and ElectroScience Laboratory at The Ohio State University, as well as Associate Editor for IEEE Antennas and Wireless Propagation Letters. He is a recipient of the NSF CAREER Award and the triennial USNC-URSI Booker Fellowship.

Table of Contents

Prefacep. xi
Introductionp. 1
Definition of Propagationp. 1
Propagation and Systems Designp. 2
Historical Perspectivep. 3
The Influence of Signal Frequency and Environmentp. 4
Propagation Mechanismsp. 6
Summaryp. 12
Sources of Further Informationp. 14
Overview of Textp. 15
Characterization of Propagation Mediap. 17
Introductionp. 17
Maxwell's Equations, Boundary Conditions, and Continuityp. 17
Constitutive Relationsp. 19
Dielectric Behavior of Materials: Material Polarizationp. 20
Material Propertiesp. 21
Simple Mediap. 22
Magnetic and Conductive Behavior of Materialsp. 30
Equivalence of Ohmic and Polarization Lossesp. 30
Referencesp. 34
Plane Wavesp. 36
Introductionp. 36
D'Alembert's Solutionp. 37
Pure Traveling Wavesp. 39
Information Transmissionp. 41
Sinusoidal Time Dependence in an Ideal Mediump. 42
Plane Waves in Lossy and Dispersive Mediap. 46
Phase and Group Velocityp. 49
Wave Polarizationp. 52
Referencesp. 55
Antenna and Noise Conceptsp. 56
Introductionp. 56
Antenna Conceptsp. 56
Basic Parameters of Antennasp. 57
Receiving Antennasp. 62
Noise Considerationsp. 66
Internal Noisep. 66
External Noisep. 68
Referencesp. 75
Direct Transmissionp. 76
Introductionp. 76
Friis Transmission Formulap. 77
Including Losses in the Friis Formulap. 78
Atmospheric Gas Attenuation Effectsp. 80
Total Attenuation on Horizontal or Vertical Atmospheric Pathsp. 82
Total Attenuation on Slant Atmospheric Pathsp. 83
Attenuation at Higher Frequencies and Further Information Sourcesp. 84
Rain Attenuationp. 85
Describing Rainp. 87
Computing Rain Specific Attenuationp. 89
A Simplified Form for Rain Specific Attenuationp. 90
Computing the Total Path Attenuation Through Rainp. 92
Attenuation Statisticsp. 96
Frequency Scalingp. 97
Rain Margin Calculations: An Examplep. 98
Site Diversity Improvementsp. 99
Scintillationsp. 102
Look Angles to Geostationary Satellitesp. 103
Referencesp. 105
Reflection and Refractionp. 106
Introductionp. 106
Reflection from a Planar Interface: Normal Incidencep. 106
Reflection from a Planar Interface: Oblique Incidencep. 108
Plane of Incidencep. 109
Perpendicular Polarized Fields in Regions 1 and 2p. 110
Phase Matching and Snell's Lawp. 111
Perpendicular Reflection Coefficientp. 113
Parallel Polarized Fields in Regions 1 and 2p. 113
Parallel Reflection Coefficientp. 115
Summary of Reflection Problemp. 115
Total Reflection and Critical Anglep. 118
Refraction in a Stratified Mediump. 120
Refraction Over a Spherical Earthp. 121
Refraction in the Earth's Atmospherep. 127
Ductingp. 129
Ray-Tracing Methodsp. 132
Referencesp. 134
Terrain Reflection and Diffractionp. 135
Introductionp. 135
Propagation Over a Plane Earthp. 136
Field Received Along Path R1: The Direct Rayp. 137
Field Received Along Path R2: The Reflected Rayp. 138
Total Fieldp. 138
Height-Gain Curvesp. 140
Fresnel Zonesp. 141
Propagation Over a Plane Earth Revisited in Terms of Fresnel Zonesp. 144
Earth Curvature and Path Profile Constructionp. 145
Microwave Link Designp. 147
Distance to the Radio Horizonp. 149
Height-Gain Curves in the Obstructed Regionp. 151
Height-Gain Curves in the Reflection Regionp. 154
Path Loss Analysis Examplesp. 154
Numerical Methods for Path Loss Analysisp. 158
Conclusionp. 160
Referencesp. 160
Empirical Path Loss and Fading Modelsp. 161
Introductionp. 161
Empirical Path Loss Modelsp. 162
Review of the Flat Earth Direct plus Reflected Modelp. 163
Empirical Model Formsp. 164
Okumura-Hata Modelp. 164
COST-231/Hata Modelp. 166
Lee Modelp. 167
Site-General ITU Indoor Modelp. 168
Other Models for Complex Terrainp. 168
An Example of Empirical Path Loss Model Usagep. 168
Signal Fadingp. 170
A Brief Review of Probability Theoryp. 172
Statistical Characterization of Slow Fadingp. 174
Statistical Characterization of Narrowband Fast Fadingp. 176
Example Fading Analysesp. 183
Narrowband Fading Mitigation Using Diversity Schemesp. 184
Wideband Channelsp. 185
Coherence Bandwidth and Delay Spreadp. 185
Coherence Time and Doppler Spreadp. 186
Conclusionp. 187
Referencesp. 187
Groundwave Propagationp. 189
Introductionp. 189
Planar Earth Groundwave Predictionp. 190
Elevated Antennas: Planar Earth Theoryp. 194
Spherical Earth Groundwave Predictionp. 196
Methods for Approximate Calculationsp. 199
A 1 MHz Sample Calculationp. 200
A 10 MHz Sample Calculationp. 203
ITU Information and Other Resourcesp. 204
Summaryp. 205
Spherical Earth Groundwave Computationsp. 211
Referencesp. 213
Characteristics of the Ionospherep. 214
Introductionp. 214
The Barometric Lawp. 215
Chapman's Theoryp. 218
Introductionp. 218
Mathematical Derivationp. 219
Structure of the Ionospherep. 226
Variability of the Ionospherep. 229
Referencesp. 233
Ionospheric Propagationp. 235
Introductionp. 235
Dielectric Properties of an Ionized Mediump. 237
Propagation in a Magnetoionic Mediump. 240
Mathematical Derivation of the Appleton-Hartree Equationp. 241
Physical Interpretationp. 247
Ordinary and Extraordinary Wavesp. 247
The QL and QT Approximationsp. 248
Ionospheric Propagation Characteristicsp. 249
Ionospheric Soundingp. 250
Ionogramsp. 251
Examples of Actual Ionogramsp. 254
The Secant Lawp. 257
Transmission Curvesp. 258
Breit and Tuve's Theoremp. 260
Martyn's Theorem on Equivalent Virtual Heightsp. 261
MUF, "Skip" Distance, and Ionospheric Signal Dispersionp. 262
Earth Curvature Effects and Ray-Tracing Techniquesp. 266
Ionospheric Propagation Prediction Toolsp. 267
Ionospheric Absorptionp. 268
Ionospheric Effects on Earth-Space Linksp. 270
Faraday Rotationp. 271
Group Delay and Dispersionp. 273
Ionospheric Scintillationsp. 275
Attenuationp. 277
Ionospheric Refractionp. 278
Monitoring TEC Distributionp. 278
Referencesp. 280
Other Propagation Mechanisms and Applicationsp. 282
Introductionp. 282
Tropospheric Scatterp. 282
Introductionp. 282
Empirical Model for the Median Path Lossp. 285
Fading in Troposcatter Linksp. 285
Meteor Scatterp. 286
Tropospheric Delay in Global Satellite Navigation Systemsp. 288
Propagation Effects on Radar Systemsp. 291
Referencesp. 293
Indexp. 295
Table of Contents provided by Ingram. All Rights Reserved.

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