Handbook of Antennas for EMC / Thereza M. MacNamara and John McAuley.

Format:

Book

Author/Creator:

Macnamara, Thereza, author.

McAuley, John (Engineer), author.

Series:

Artech House antennas and electromagnetics analysis library.

Artech House antenna and electromagnetics analysis series

Language:

English

Subjects (All):

Electromagnetic compatibility.

Physical Description:

1 online resource : illustrations

Edition:

Second edition.

Place of Publication:

Norwood, Massachusetts : Artech House, [2018]

Summary:

Offering a thorough understanding of the practical aspects and underpinnings of antennas in EMC systems, this invaluable resource provides the knowledge needed to determine the right antenna for specific applications and offers guidance in conducting EMC testing. -- Edited summary from book.

Contents:

Handbook of Antennas for EMC Second Edition

Contents

Preface

Chapter 1 Introduction to Antennas

1.1 Requirements of an Antenna for EMC

1.1.1 Types of Antennas

1.2 Main Characteristics of an Antenna

1.2.1 Radiation Resistance

1.2.2 Radiation Pattern

1.2.3 Main Lobe

1.2.4 Sidelobe

1.2.5 Front-to-Back Ratio

1.2.6 Bandwidth

1.2.7 Aperture Size

1.2.8 Antenna Correction Factors

1.2.9 Polarization

1.2.10 Relationships Between the Key Parameters

References

Chapter 2 Basic Math for EMC Engineers

2.1 Angles

2.1.1 Convention for Angles

2.2 Basic Trigonometry

2.2.1 Reciprocal Trigonometric Functions

2.2.2 Inverse Trigonometric Functions

2.3 Powers, Indices, and Logarithms

2.3.1 Multiplication of Numbers

2.3.2 Relationship Between dBm and dBmV

2.4 Real and Complex Numbers

2.4.1 Addition of Complex Numbers

2.4.2 Complex Conjugate

2.5 Scalars and Vectors

2.5.1 Position Vector

2.5.2 Vector Addition and Subtraction

2.5.3 Vector Multiplication

2.5.4 Phasors

2.6 Fourier Analysis and Transforms

2.6.1 Fourier Analysis

2.6.2 Fourier Transforms

2.7 Parameters

2.7.1 Mathematical Definition of Parameters

2.8 Fundamental Units and Dimensions

2.8.1 Checking Formulas by Dimensions

Chapter 3 Antenna Theory

3.1 Unit Vectors

3.2 Scalar and Vector Fields

3.2.1 Spatial Rates of Change of Scalar and Vector Fields

3.2.2 Gradient of a Scalar Field

3.2.3 Divergence of a Vector Field

3.2.4 Curl of a Vector

3.3 Maxwell's Equations

3.3.1 Maxwell's First Equation

3.3.2 Maxwell's Second Equation

3.3.3 Maxwell's third equation

3.3.4 Maxwell's Fourth Equation

3.4 Boundary Conditions

3.4.1 Tangential Component of the Electric Field

3.4.2 Tangential Component of the Magnetic Field.

3.4.3 Normal Component of the Electric Field

3.4.4 Normal Component of the Magnetic Field

3.5 Fields Due to a Radiating Dipole

3.5.1 Field Due to a Current Element

3.5.2 Fields at Large Distances from Wire Antennas

3.6 Power Flux Density for a Plane Wave

3.7 Wave Impedance for a Plane Wave

3.8 Radiation Resistance

3.9 Far Field of Antennas

3.9.1 Far Field for Wire Antennas

3.9.2 Far Field for Aperture Antennas

Chapter 4 Antennas for Frequencies Below 1 MHz

4.1 Mechanism of Radiation

4.2 Near and Far Fields of Antennas

4.3 Wave Impedance

4.4 Difference Between Receiving and Transmitting Antennas

4.5 Small Antennas

4.6. Baluns

4.7 Radiation Power Factor

4.7.1 Operating Efficiency

4.8 Matching Antennas

4.9 Effective Length and Effective Height

4.9.1 Effective Length

4.9.2 Effective Height

4.10 E-Field Antennas

4.10.1 Small Dipole

4.10.2 Short Monopoles

4.10.3 Ground Plane Dependence

4.10.4 Top-Loaded Monopoles

4.10.5 Parallel Element E-Field Generator

4.11 H-Field Antennas

4.11.1 Helmholtz Coils

4.11.2 Small Magnetic Loops

4.11.3 Single-Turn Shielded Loops

4.11.4 Simple Multiturn Loop Probe

Chapter 5 Antennas for Frequencies Between 1 MHz and 1 GHz

5.1 Resonant Monopoles

5.2 Discone Antenna

5.3 Cavitenna

5.4 Resonant and Large Dipoles

5.5 Folded Dipoles

5.6 Triangular Dipoles

5.7 Biconical Antennas

5.8 Yagi-Uda Antenna

5.9 Frequency-Independent Antennas

5.10 Log Periodic Antenna

5.11 BiLog®

5.12 Helical Antennas

5.13 Large and Resonant Loops

5.14 Double-Ridged Horn

Selected Bibliography

Chapter 6 Antennas for Frequencies Above 1 GHz

6.1 Frequency-Independent Antennas

6.2 Band Theory

6.3 Log Spiral

6.3.1 Modes of Radiation.

6.3.2 Rotation of Radiation Pattern with Frequency

6.3.3 Planar Log Spiral

6.3.4 Slot Planar Log Spiral

6.3.5 Cavity-Backed Spiral

6.3.6 Conical Log Spiral

6.4 Archimedes Spiral

6.4.1 Cavity-Backed Archimedean Spiral

6.5 Microstrip Planar Spiral

6.6 Discone Antenna

6.7 Double-Ridged Horns

6.7.1 Waveguide Theory

6.7.2 Modes in Square and Rectangular Waveguides

6.7.3 Double-Ridged Waveguides

6.7.4 Double-Ridged Waveguide Horns

Chapter 7 Calibration of Antennas

7.1 Gain

7.1.1 Measurement of Gain

7.1.2 Purcell's Method

7.1.3 Two-Antenna Method

7.1.4 Three-Antenna Method

7.2 Calculation of Gain

7.2.1 E-Plane Sectoral Horn

7.2.2 H-Plane Sectoral Horn

7.2.3 Gain of a Pyramidal Horn

7.3 Example

7.3.1 Accurate Method

7.3.2 Semi-Accurate Method

7.3.3 Approximate Method

7.4 Antenna Correction Factor

Chapter 8 Introduction to Electromagnetic Compatibility Measurements

8.1 Radiated Emissions

8.1.1 Differential and Common Mode Radiation

8.1.2 Measurement of Radiated Emissions

8.1.3 Classes of Computer Equipment

8.1.4 Measuring Radiated EMI

8.2 Radiated Susceptibility and Immunity

8.2.1 Immunity to Radiated Electric Field Strength

8.2.2 Immunity to Conducted Radiated Interference

8.2.3 Magnetic Field Immunity

8.2.4 Immunity to Electrical Fast Transients

8.2.5 Immunity to Electrostatic Discharges

8.3 Conducted Emissions and Immunity

8.3.1 Immunity to Conducted Common- and Differential-Mode Voltages

8.4 Shielding Effectiveness of Solid Materials

8.4.1 Reflection Loss

8.4.2 Absorption Loss

8.4.3 Multiple Reflection Loss

8.4.4 Total Shielding Effectiveness

8.5 Measuring Shielding Effectiveness

8.5.1 Magnetic or H-Mode SE Measurements.

8.5.2 Electric or E-Mode SE Measurements

8.5.3 Plane Wave SE Measurements

8.5.4 Ventilation Holes

8.6 Electrostatic Discharge

8.6.1 ESD Spectrum

8.6.2 Direct and Indirect ESD

8.6.3 ESD Models

8.6.4 Testing for ESD Susceptibility

8.7 Instrumentation

8.7.1 Measuring Receivers

8.7.2 Spectrum Analyzers

Chapter 9 Theory and Applications of Measurement Sites and Enclosures

Appendix A List of Acronyms and Abbreviations

9.1 TEM Waves

9.1.1 Power Flux Density

9.1.2 Wave Impedance

9.1.3 TEM Transmission Lines

9.2 TEM Cells

9.2.1 Parallel Stripline Cells

9.2.2 Circular Coaxial TEM Cells

9.2.3 Rectangular and Square TEM Cells

9.3 Modes in Circular Waveguides

9.3.1 Cut-Off Waveguide Ventilation Panels

9.4 Resonant Cavities

9.4.1 Degeneracy

9.4.2 Mode Stirrers

9.5 Shielded Rooms

9.5.1 Unlined Shielded or Screened Rooms

9.5.2 Absorber-Lined Chambers

9.5.3 Anechoic Chambers

9.6 Open Area Test Sites

9.6.1 Free-Space OATS

9.7 Reverberation Chamber

9.7.1 Reverberation Chamber Requirements of EN 61000-4-21

9.7.2 Validation Procedure

9.7.3 Testing an EUT

9.7.4 Immunity Testing

9.8 Radiated Emissions

9.8.1 Free-Space Field

Appendix A

Appendix B Preferred Scientific Prefixes

Appendix C List of Scientific Constants

Appendix D Conductivities of Common Metals

Appendix E Dielectric Constants and Loss Tangents of Common Materials

Appendix F Conversion Table for dBμV to μV, dBV, dBW, dBm, and Watts

Appendix G The Electromagnetic Spectrum

Appendix H Frequency Band Designations

Appendix I Conversion Between Gain in dB and Gain as a Linear Ratio Gain in dBi to Linear Gain

Appendix J The Periodic Table Listed Alphabetically by Chemical Symbol.

Appendix K Magnetic Permeabilities of Common Metals

Appendix L Polarization Matching Matrix

Appendix M Resistivities of Common Materials

Appendix N Radio Frequency Protection Guides For Nonionising Radiation

Appendix O List of Symbols

About the Author

Index.

Notes:

Print version record.

Includes bibliographical references and index.

Description based on print version record.

Other Format:

Print version: Macnamara, Thereza. Handbook of Antennas for EMC.

ISBN:

9781630814267

1630814261

OCLC:

1089316031