Radio Propagation and Adaptive Antennas for Wireless Communication Links: Terrestrial, Atmospheric and Ionospheric (Hardcover) (無線通信鏈路的無線電傳播與自適應天線:地面、大氣與電離層)

Nathan Blaunstein, Christos Christodoulou

  • 出版商: Wiley
  • 出版日期: 2006-10-20
  • 售價: $1,450
  • 貴賓價: 9.8$1,421
  • 語言: 英文
  • 頁數: 614
  • 裝訂: Hardcover
  • ISBN: 0471251216
  • ISBN-13: 9780471251217
  • 相關分類: 天線相關 Antennas
  • 下單後立即進貨 (約5~7天)

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商品描述

Description

Antennas and Propogation for Wireless Communication covers the basics of wireless communication system design with emphasis on antennas and propagation. It contains information on antenna fundamentals and the latest developments in smart antennas, as well as the radiation effects of hand-held devices.

Antennas and Propogation for Wireless Communication provides a complete discussion of all the topics important to the design of wireless communication systems. Written by acknowledged authorities in their respective fields, the book deals with practical applications and presents real world examples. A solutions manual for college adopters accompanies the text. Ideal for engineers working in communication, antennas, and propagation for telecomm, military, and aerospace applications, as well as students of electrical engineering, this book covers all topics needed for a complete system design.

 

Table of Contents

Preface.

Chapter One: Fundamentals of Radio Communications.

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. Problems in Adaptive Antennas Application.

Bibliography.

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.

Bibliography.

Chapter Three: Fundamentals of Wave Propagation in Random Media.

3.1. Main Wave Equations and Random Functions.

3.2. The Perturbation Method for Multiple Scattering.

The Mean Perturbed Propagator.

The Mean Double Propagator.

Mass Operator and Dyson Equation.

3.3. An Exact Solution of 1D-Equation.

3.4. Approximations of the Perturbation Method.

3.5. Random Taylor Expansion at Short Wavelengths.

3.6. An Exact Solution of the Scalar Wave Equation.

Approximate Evaluations of the Functional Integral (3.137).

3.7. The Electromagnetic Wave Equation.

3.8. Propagation in Statistically Inhomogeneous Media.

3.9. Propagation in Homogeneous Anisotropic Media.

Bibliography.

Chapter Four: Electromagnetic Aspects of Wave Propagation over Terrain.

4.1. Waves Propagation in Free Space.

4.2. Path Loss in Free Space.

4.3. Radio Propagation Above Flat Terrain.

4.4. Propagation Above Rough Terrain Under LOS Conditions.

4.5. Propagation Above a Smooth Curved Terrain.

4.6. Effect of a Single Obstacle Placed on a Flat Terrain.

Bibliography.

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. Effect of a Building on the Radio Propagation Channel.

5.6. Propagation in Rural Forest Environments.

5.6.1. A Model of Multiple Scattering in a Forested Area.

5.6.2. Comparison with Other Models.

5.7. Propagation in Mixed Residential Areas.

5.8. Propagation in Urban Environments.

Bibliography.

Chapter Six: Effects of the Troposphere on Radio Propagation.

6.1. Main Propagation Effects of the Troposphere as a Spherical Layered Gaseous Continuum.

6.2. Effects of the Hydrometeors on Radio Propagation in the Troposphere.

6.3. Effects of Tropospheric Turbulences on Radio Propagation.

6.4. Link Budget Design for Tropospheric Communication Links.

Bibliography.

Chapter Seven: Ionospheric Radio Propagation.

7.1. Main Ionospheric Effects on Radio Propagation.

7.2. Effects of the Inhomogeneous Ionosphere on Radio Propagation.

7.3. Back and Forward Scattering of Radio Waves by Small-Scale Ionospheric Inhomogeneities.

Bibliography.

Chapter Eight: Indoor Radio Propagation.

8.1. Main Propagation Processes and Characteristics.

8.2. Modeling of Loss Characteristics in Various Indoor Environments.

8.3. Link Budget Design Verification by Experimental Data.

Bibliography.

Chapter Nine: Adaptive Antennas for Wireless Networks.

9.1. Antenna Arrays.

9.2. Beamforming Techniques.

9.3. Adaptive Antenna for Wireless Communication Applications.

9.4. Network Performance Improvement Using an Antenna Array.

Summary.

Bibliography.

Chapter Ten: Prediction of Signal Distribution in Space, Time and Frequency Domains in Radio Channels for Adaptive Antenna Applications.

10.1. Predicting Models for Indoor Communication Channels.

10.2. Predicting Models for Outdoor Communication Channels.

10.3. Experimental Verification of Signal Power Distribution in Azimuth, Elevation, and Time Delay Domains.

10.4. Signal Power Spectra Distribution in Frequency Shift Domain.

Bibliography.

Chapter Eleven: Multipath Fading Phenomena in Land Wireless Links.

11.1. Prediction of Loss Characteristics for Land Radio Links.

11.2. Link Budget Design for Various Land Environments.

11.3. Characterization of Multipath Radio Channel by Rician Factor.

11.4. Main Algorithm of Radio Coverage (Radio Map) Design.

Bibliography.

Chapter Twelve: Cellular Communication Networks Design Based on Radio Propagation Phenomena.

12.1. Grade of Service (GOS) Design Operating in Multipath Fading Environment.

12.2. Propagation Aspects of Cell Planning.

12.3. Prediction of Parameters of Information Data Stream.

Channel Capacity and Spectral Efficiency.

Relations Between Main Parameters.

Bibliography.

Chapter Thirteen: Prediction of Operational Characteristics of Adaptive Antennas.

13.1. Experimental Verification of Signal Distribution in Azimuth, Time Delay, and Doppler Shift Domains.

13.2. Prediction of Adaptive Antenna Characteristics Based on Unified Stochastic Approach.

Bibliography.

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. The Unified Algorithm for Fading Phenomena Prediction.

14.6. Mega-Cell Concept for Land Satellite Communication Links.

14.7. ‘‘Mega-Cell’’ Global Networks Design.

Summary.

Bibliography.

Index.

商品描述(中文翻譯)

《無線通訊的天線與傳播》涵蓋了無線通訊系統設計的基礎知識,重點放在天線和傳播上。書中包含了有關天線基礎知識和智能天線的最新發展,以及手持設備的輻射效應。《無線通訊的天線與傳播》提供了一個完整的討論,涵蓋了設計無線通訊系統所需的所有重要主題。該書由各自領域的公認專家撰寫,涉及實際應用並提供真實世界的例子。該書附有大學採用者的解答手冊。這本書非常適合從事通訊、天線和傳播領域的工程師,以及電氣工程學的學生,涵蓋了完成系統設計所需的所有主題。

目錄:
前言
第一章:無線通訊基礎
1.1 無線通訊連接
1.2 無線通訊頻段
1.3 無線通訊連接中的噪聲
1.4 主要傳播特性
1.5 自適應天線應用中的問題
參考文獻
第二章:天線基礎知識
2.1 輻射圖案
2.2 天線的場區域
2.3 輻射強度
2.4 定向性和增益
2.5 偏振
2.6 自由空間中的終端天線
2.7 天線類型
參考文獻
第三章:隨機媒介中的波傳播基礎
3.1 主要波動方程和隨機函數
3.2 多重散射的擾動方法
平均擾動傳播子
平均雙重傳播子
質量運算子和Dyson方程
3.3 一維方程的精確解
3.4 擾動方法的近似
3.5 短波長處的隨機泰勒展開
3.6 标量波動方程的精確解
在功能積分(3.137)的近似評估
3.7 電磁波動方程
3.8 在統計非均勻媒介中的傳播
3.9 在均勻異向媒介中的傳播
參考文獻
第四章:地形上的波傳播的電磁方面
4.1 自由空間中的波傳播
4.2 自由空間中的路徑損耗
4.3 平坦地形上的傳播
4.4 在LOS條件下的崎嶇地形上的傳播
4.5 在光滑彎曲地形上的傳播
4.6 在平坦地形上放置單個障礙物的影響
參考文獻
第五章:地面無線通訊
5.1 地形的特徵
5.2 地面通訊連接中的傳播場景
5.3 在LOS條件下的平坦地形上的傳播
5.4 在NLOS條件下的崎嶇地形上的傳播
5.5 建築物對無線傳播通道的影響
5.6 在鄉村森林環境中的傳播
5.6.1 森林區域的多重散射模型
5.6.2 與其他模型的比較
5.7 在混合住宅區的傳播
5.8 在城市環境中的傳播