Description

Book Synopsis
An accessible student-oriented approach to radiowave propagation

Propagation-the process whereby a signal is conveyed between transmitter and receiver-has a profound influence on communication systems design. Radiowave Propagation provides an overview of the physical mechanisms that govern electromagnetic wave propagation in the Earth''s troposphere and ionosphere. Developed in conjunction with a graduate-level wave propagation course at The Ohio State University, this text offers a balance of physical and empirical models to provide basic physical insight as well as practical methods for system design.

Beginning with discussions of propagation media properties, plane waves, and antenna and system concepts, successive chapters consider the most important wave propagation mechanisms for frequencies ranging from LF up to the millimeter wave range, including:

  • Direct line-of-sight propagation through the atmosphere

  • Rain attenuatio

    Trade Review

    “It is highly recommended for any RF engineer who is concerned with the effects of the propagation channel on his or her system’s performance.” (International Union of Radio Science, 1 March 2012)



    Table of Contents
    Preface.

    1 Introduction.

    1.1 Definition of Propagation.

    1.2 Propagation and Systems Design.

    1.3 Historical Perspective.

    1.4 The Influence of Signal Frequency and Environment.

    1.5 Propagation Mechanisms.

    1.6 Summary.

    1.7 Sources of Further Information.

    1.8 Overview of Text.

    2 Characterization of Propagation Media.

    2.1 Introduction.

    2.2 Maxwell’s Equations, Boundary Conditions, and Continuity.

    2.3 Constitutive Relations.

    2.4 Dielectric Behavior of Materials: Material Polarization.

    2.5 Material Properties.

    2.5.1 Simple Media.

    2.6 Magnetic and Conductive Behavior of Materials.

    References.

    3 Plane Waves.

    3.1 Introduction.

    3.2 D’Alembert’s Solution.

    3.3 Pure Traveling Waves.

    3.4 Information Transmission.

    3.5 Sinusoidal Time Dependence in an Ideal Medium.

    3.6 Plane Waves in Lossy and Dispersive Media.

    3.7 Phase and Group Velocity.

    3.8 Wave Polarization.

    References.

    4 Antenna and Noise Concepts.

    4.1 Introduction.

    4.2 Antenna Concepts.

    4.3 Basic Parameters of Antennas.

    4.3.1 Receiving Antennas.

    4.4 Noise Considerations.

    References.

    5 Direct Transmission.

    5.1 Introduction.

    5.2 Friis Transmission Formula.

    5.3 Atmospheric Gas Attenuation Effects.

    5.4 Rain Attenuation.

    5.5 Scintillations.

    Appendix 5.A Look Angles to Geostationary Satellites.

    References.

    6 Reflection and Refraction.

    6.1 Introduction.

    6.2 Reflection from a Planar Interface: Normal Incidence.

    6.3 Reflection from a Planar Interface: Oblique Incidence.

    6.4 Total Reflection and Critical Angle.

    6.5 Refraction in a Stratified Medium.

    6.6 Refraction Over a Spherical Earth.

    6.7 Refraction in the Earth’s Atmosphere.

    6.8 Ducting.

    6.9 Ray-Tracing Methods.

    References.

    7 Terrain Reflection and Diffraction.

    7.1 Introduction.

    7.2 Propagation Over a Plane Earth.

    7.3 Fresnel Zones.

    7.4 Earth Curvature and Path Profile Construction.

    7.5 Microwave Link Design.

    7.6 Path Loss Analysis Examples.

    7.7 Numerical Methods for Path Loss Analysis.

    7.8 Conclusion.

    References.

    8 Empirical Path Loss and Fading Models.

    8.1 Introduction.

    8.2 Empirical Path Loss Models.

    8.3 Signal Fading.

    8.4 Narrowband Fading Mitigation Using Diversity Schemes.

    8.5 Wideband Channels.

    8.6 Conclusion.

    References.

    9 Groundwave Propagation.

    9.1 Introduction.

    9.2 Planar Earth Groundwave Prediction.

    9.3 Spherical Earth Groundwave Prediction.

    9.4 Methods for Approximate Calculations.

    9.5 A 1 MHz Sample Calculation.

    9.6 A 10 MHz Sample Calculation.

    9.7 ITU Information and Other Resources.

    9.8 Summary.

    Appendix 9.A Spherical Earth Groundwave Computations.

    References.

    10 Characteristics of the Ionosphere.

    10.1 Introduction.

    10.2 The Barometric Law.

    10.3 Chapman’s Theory.

    10.4 Structure of the Ionosphere.

    10.5 Variability of the Ionosphere.

    References.

    11 Ionospheric Propagation.

    11.1 Introduction.

    11.2 Dielectric Properties of an Ionized Medium.

    11.3 Propagation in a Magnetoionic Medium.

    11.4 Ionospheric Propagation Characteristics.

    11.5 Ionospheric Sounding.

    11.6 The Secant Law.

    11.7 Transmission Curves.

    11.8 Breit and Tuve’s Theorem.

    11.9 Martyn’s Theorem on Equivalent Virtual Heights.

    11.10 MUF, "Skip" Distance, and Ionospheric Signal Dispersion.

    11.11 Earth Curvature Effects and Ray-Tracing Techniques.

    11.12 Ionospheric Propagation Prediction Tools.

    11.13 Ionospheric Absorption.

    11.14 Ionospheric Effects on Earth–Space Links.

    References.

    12 Other Propagation Mechanisms and Applications.

    12.1 Introduction.

    12.2 Tropospheric Scatter.

    12.3 Meteor Scatter.

    12.4 Tropospheric Delay in Global Satellite Navigation Systems.

    12.5 Propagation Effects on Radar Systems.

    References.

    Index.

Radiowave Propagation

Product form

£97.16

Includes FREE delivery

RRP £107.95 – you save £10.79 (9%)

Order before 4pm today for delivery by Sat 20 Dec 2025.

A Hardback by Curt Levis, Joel T. Johnson, Fernando L. Teixeira

Out of stock


    View other formats and editions of Radiowave Propagation by Curt Levis

    Publisher: John Wiley & Sons Inc
    Publication Date: 18/06/2010
    ISBN13: 9780470542958, 978-0470542958
    ISBN10: 0470542950
    Also in:
    Electricity, electromagnetism and magnetism

    Description

    Book Synopsis
    An accessible student-oriented approach to radiowave propagation

    Propagation-the process whereby a signal is conveyed between transmitter and receiver-has a profound influence on communication systems design. Radiowave Propagation provides an overview of the physical mechanisms that govern electromagnetic wave propagation in the Earth''s troposphere and ionosphere. Developed in conjunction with a graduate-level wave propagation course at The Ohio State University, this text offers a balance of physical and empirical models to provide basic physical insight as well as practical methods for system design.

    Beginning with discussions of propagation media properties, plane waves, and antenna and system concepts, successive chapters consider the most important wave propagation mechanisms for frequencies ranging from LF up to the millimeter wave range, including:

    • Direct line-of-sight propagation through the atmosphere

    • Rain attenuatio

      Trade Review

      “It is highly recommended for any RF engineer who is concerned with the effects of the propagation channel on his or her system’s performance.” (International Union of Radio Science, 1 March 2012)



      Table of Contents
      Preface.

      1 Introduction.

      1.1 Definition of Propagation.

      1.2 Propagation and Systems Design.

      1.3 Historical Perspective.

      1.4 The Influence of Signal Frequency and Environment.

      1.5 Propagation Mechanisms.

      1.6 Summary.

      1.7 Sources of Further Information.

      1.8 Overview of Text.

      2 Characterization of Propagation Media.

      2.1 Introduction.

      2.2 Maxwell’s Equations, Boundary Conditions, and Continuity.

      2.3 Constitutive Relations.

      2.4 Dielectric Behavior of Materials: Material Polarization.

      2.5 Material Properties.

      2.5.1 Simple Media.

      2.6 Magnetic and Conductive Behavior of Materials.

      References.

      3 Plane Waves.

      3.1 Introduction.

      3.2 D’Alembert’s Solution.

      3.3 Pure Traveling Waves.

      3.4 Information Transmission.

      3.5 Sinusoidal Time Dependence in an Ideal Medium.

      3.6 Plane Waves in Lossy and Dispersive Media.

      3.7 Phase and Group Velocity.

      3.8 Wave Polarization.

      References.

      4 Antenna and Noise Concepts.

      4.1 Introduction.

      4.2 Antenna Concepts.

      4.3 Basic Parameters of Antennas.

      4.3.1 Receiving Antennas.

      4.4 Noise Considerations.

      References.

      5 Direct Transmission.

      5.1 Introduction.

      5.2 Friis Transmission Formula.

      5.3 Atmospheric Gas Attenuation Effects.

      5.4 Rain Attenuation.

      5.5 Scintillations.

      Appendix 5.A Look Angles to Geostationary Satellites.

      References.

      6 Reflection and Refraction.

      6.1 Introduction.

      6.2 Reflection from a Planar Interface: Normal Incidence.

      6.3 Reflection from a Planar Interface: Oblique Incidence.

      6.4 Total Reflection and Critical Angle.

      6.5 Refraction in a Stratified Medium.

      6.6 Refraction Over a Spherical Earth.

      6.7 Refraction in the Earth’s Atmosphere.

      6.8 Ducting.

      6.9 Ray-Tracing Methods.

      References.

      7 Terrain Reflection and Diffraction.

      7.1 Introduction.

      7.2 Propagation Over a Plane Earth.

      7.3 Fresnel Zones.

      7.4 Earth Curvature and Path Profile Construction.

      7.5 Microwave Link Design.

      7.6 Path Loss Analysis Examples.

      7.7 Numerical Methods for Path Loss Analysis.

      7.8 Conclusion.

      References.

      8 Empirical Path Loss and Fading Models.

      8.1 Introduction.

      8.2 Empirical Path Loss Models.

      8.3 Signal Fading.

      8.4 Narrowband Fading Mitigation Using Diversity Schemes.

      8.5 Wideband Channels.

      8.6 Conclusion.

      References.

      9 Groundwave Propagation.

      9.1 Introduction.

      9.2 Planar Earth Groundwave Prediction.

      9.3 Spherical Earth Groundwave Prediction.

      9.4 Methods for Approximate Calculations.

      9.5 A 1 MHz Sample Calculation.

      9.6 A 10 MHz Sample Calculation.

      9.7 ITU Information and Other Resources.

      9.8 Summary.

      Appendix 9.A Spherical Earth Groundwave Computations.

      References.

      10 Characteristics of the Ionosphere.

      10.1 Introduction.

      10.2 The Barometric Law.

      10.3 Chapman’s Theory.

      10.4 Structure of the Ionosphere.

      10.5 Variability of the Ionosphere.

      References.

      11 Ionospheric Propagation.

      11.1 Introduction.

      11.2 Dielectric Properties of an Ionized Medium.

      11.3 Propagation in a Magnetoionic Medium.

      11.4 Ionospheric Propagation Characteristics.

      11.5 Ionospheric Sounding.

      11.6 The Secant Law.

      11.7 Transmission Curves.

      11.8 Breit and Tuve’s Theorem.

      11.9 Martyn’s Theorem on Equivalent Virtual Heights.

      11.10 MUF, "Skip" Distance, and Ionospheric Signal Dispersion.

      11.11 Earth Curvature Effects and Ray-Tracing Techniques.

      11.12 Ionospheric Propagation Prediction Tools.

      11.13 Ionospheric Absorption.

      11.14 Ionospheric Effects on Earth–Space Links.

      References.

      12 Other Propagation Mechanisms and Applications.

      12.1 Introduction.

      12.2 Tropospheric Scatter.

      12.3 Meteor Scatter.

      12.4 Tropospheric Delay in Global Satellite Navigation Systems.

      12.5 Propagation Effects on Radar Systems.

      References.

      Index.

    Recently viewed products

    © 2025 Book Curl

      • American Express
      • Apple Pay
      • Diners Club
      • Discover
      • Google Pay
      • Maestro
      • Mastercard
      • PayPal
      • Shop Pay
      • Union Pay
      • Visa

      Login

      Forgot your password?

      Don't have an account yet?
      Create account