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Index
Cover Table of Contents Wiley Series in Microwave and Optical Engineering Title page Copyright page Preface PART I: Fundamentals of Wireless Links and Networks
CHAPTER ONE: Wireless Communication Links with Fading
1.1.  Radio Communication Link 1.2.  Frequency Band for Radio Communications 1.3.  Noise in Radio Communication Links 1.4.  Main Propagation Characteristics 1.5.  High-Level Fading Statistical Parameters 1.6.  Adaptive Antennas Application References
CHAPTER TWO: Antenna Fundamentals
2.1.  Radiation Pattern 2.2.  Field Regions of an Antenna 2.3.  Radiation Intensity 2.4.  Directivity and Gain 2.5.  Polarization 2.6.  Terminal Antennas in Free Space 2.7.  Antenna Types References
CHAPTER THREE: Fundamentals of Wireless Networks
3.1.  Cellular Networks Concept 3.2.  Spread Spectrum Modulation 3.3.  Multiple Access Technologies and Networks 3.4.  Capacity of Information Data in Multiple Access Networks Exercises References
PART II: Fundamentals of Radio Propagation
CHAPTER FOUR: Electromagnetic Aspects of Wave Propagation over Terrain
4.1.  Wave Propagation in Free Space 4.2.  Path Loss in Free Space 4.3.  Radio Propagation above Flat Terrain 4.4.  Propagation above Rough Terrain in LOS Conditions 4.5.  Propagation above a Smooth Curved Terrain 4.6.  Effect of a Single Obstacle Placed on a Flat Terrain Exercises References
CHAPTER FIVE: Terrestrial Radio Communications
5.1.  Characterization of the Terrain 5.2.  Propagation Scenarios in Terrestrial Communication Links 5.3.  Propagation over a Flat Terrain in LOS Conditions 5.4.  Propagation over a Hilly Terrain in NLOS Conditions 5.5.  Propagation in Rural Forest Environments 5.6.  Propagation in Mixed Residential Areas 5.7.  Propagation in Urban Environments 5.8.  Distribution of Polarized Parameters in Urban Environments with Multipath References
CHAPTER SIX: Indoor Radio Propagation
6.1.  Main Propagation Processes and Characteristics 6.2.  Modeling of Loss Characteristics in Various Indoor Environments 6.3.  Link Budget Design Verification by Experimental Data References
PART III: Fundamentals of Adaptive Antennas
CHAPTER SEVEN: Adaptive Antennas for Wireless Networks
7.1.  Antenna Arrays 7.2.  Beamforming Techniques 7.3.  Adaptive Antenna for Wireless Communication Applications 7.4.  Network Performance Improvement Using an Antenna Array 7.5.  Conclusion References
CHAPTER EIGHT: Prediction of Signal Distribution in Space, Time, and Frequency Domains in Radio Channels for Adaptive Antenna Applications
8.1.  Predicting Models for Outdoor Communication Channels 8.2.  2-D and 3-D Stochastic Multiparametric Model 8.3.  3-D Stochastic Model Accounting for Straight Crossing Street Grid 8.4.  Effects of Depolarization in the Azimuth and Elevation Domains 8.5.  Predicting Models for Indoor Communication Channels 8.6.  Experimental Verification of Signal Distribution in AOA, EOA, and TOA Domains for Outdoor Communications 8.7.  Experimental Verification of Signal Distribution in Joint AOA-TOA and TOA-Distance Domains in Indoor Communications 8.8.  Signal Power Spectra Distribution in Doppler Spread Domain References
CHAPTER NINE: Prediction of Operational Characteristics of Adaptive Antennas
9.1.  Experimental Verification of Signal Distribution in Azimuth, Elevation, Time Delay, and Doppler Shift Domain 9.2.  Prediction of Adaptive Antenna Characteristics Based on Unified Stochastic Approach 9.3.  Positioning of the Desired Mobile Subscriber in Urban Environments Summary References
PART IV: Practical Aspects of Terrestrial Networks Performance: Cellular and Noncellular
CHAPTER TEN: Multipath Fading Phenomena in Terrestrial Wireless Communication Links
10.1.  Prediction of Loss Characteristics for Terrestrial Radio Links 10.2.  Link Budget Design for Various Land Environments 10.3.  Characterization of Multipath Radio Channel by the Rician Factor 10.4.  Main Algorithm of Radio Coverage (Radio Map) Design References
CHAPTER ELEVEN: Cellular and Noncellular Communication Networks Design Based on Radio Propagation Phenomena
11.1.  Grade of Service Design Operating in Multipath Fading Environment 11.2.  Propagation Aspects of Cell Planning 11.3.  Prediction of Parameters of Information Data Stream References
PART V: Atmospheric and Satellite Communication Links and Networks
CHAPTER TWELVE: Effects of the Troposphere on Radio Propagation
12.1.  Main Propagation Effects of the Troposphere as a Spherical Layered Gaseous Continuum 12.2.  Effects of Hydrometeors on Radio Propagation in the Troposphere 12.3.  Effects of Tropospheric Turbulences on Radio Propagation 12.4.  Link Budget Design for Tropospheric Communication Links References
CHAPTER THIRTEEN: Ionospheric Radio Propagation
13.1.  Main Ionospheric Effects on Radio Propagation 13.2.  Effects of the Inhomogeneous Ionosphere on Radio Propagation References
CHAPTER FOURTEEN: Land–Satellite Communication Links
14.1.  Objective 14.2.  Type of Signals in Land Satellite Communication Links 14.3.  Statistical Models 14.4.  Physical–Statistical Models 14.5.  Fading Effects Estimation in Land-Satellite Links via the Experimental Data 14.6.  Megacell Global Networks Design Summary References
Index End User License Agreement
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