Anechoic and Reverberation Chambers : Theory, Design and Measurements.

A Comprehensive Review of the Recent Advances in Anechoic Chamber and Reverberation Chamber Designs and Measurements Anechoic and Reverberation Chambers is a guide to the latest systematic solutions for designing anechoic chambers that rely on state-of-the-art computational electromagnetic algorithm...

Descripción completa

Detalles Bibliográficos
Clasificación:Libro Electrónico
Autor principal: Xu, Qian
Otros Autores: Huang, Yi
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Newark : John Wiley & Sons, Incorporated, 2018.
Temas:
Anechoic chambers.
Electromagnetic reverberation chambers.
Electromagnetic measurements.
Electromagnetic waves > Transmission.
Shielding (Electricity)
Chambres sourdes.
Mesures électromagnétiques.
Ondes électromagnétiques > Propagation.
Blindage (Électricité)
anechoic rooms.
Anechoic chambers
Electromagnetic measurements
Electromagnetic reverberation chambers
Electromagnetic waves > Transmission
Acceso en línea:Texto completo
Tabla de Contenidos:
  • Intro; Title Page; Contents; About the Authors; About the Contributors; Acknowledgements; Acronyms; Chapter 1 Introduction; 1.1 Background; 1.1.1 Anechoic Chambers; 1.1.2 Reverberation Chambers; 1.1.3 Relationship between Anechoic Chambers and Reverberation Chambers; 1.2 Organisation of this Book; References; Chapter 2 Theory for Anechoic Chamber Design; 2.1 Introduction; 2.2 Absorbing Material Basics; 2.2.1 General Knowledge; 2.2.2 Absorbing Material Simulation; 2.2.3 Absorbing Material Measurement; 2.3 CEM Algorithms Overview; 2.4 GO Theory; 2.4.1 GO from Maxwell Equations.
  • 2.4.2 Analytical Expression of a Reflected Field from a Curved Surface2.4.3 Alternative GO Form; 2.5 GO-FEM Hybrid Method; 2.6 Summary; References; Chapter 3 Computer-aided Anechoic Chamber Design; 3.1 Introduction; 3.2 Framework; 3.3 Software Implementation; 3.3.1 3D Model Description; 3.3.2 Algorithm Complexities; 3.3.3 Far-Field Data; 3.3.4 Boundary Conditions; 3.3.5 RAM Description; 3.3.6 Forward Algorithm; 3.3.7 Inverse Algorithm; 3.3.8 Post Processing; 3.4 Summary; References; Chapter 4 Anechoic Chamber Design Examples and Verifications; 4.1 Introduction; 4.2 Normalised Site Attenuation.
  • 4.2.1 NSA Definition4.2.2 NSA Simulation and Measurement; 4.3 Site Voltage Standing Wave Ratio; 4.3.1 SVSWR Definition; 4.3.2 SVSWR Simulation and Measurement; 4.4 Field Uniformity; 4.4.1 FU Definition; 4.4.2 FU Simulation and Measurement; 4.5 Design Margin; 4.6 Summary; References; Chapter 5 Fundamentals of the Reverberation Chamber; 5.1 Introduction; 5.2 Resonant Cavity Model; 5.3 Ray Model; 5.4 Statistical Electromagnetics; 5.4.1 Plane-Wave Spectrum Model; 5.4.2 Field Correlations; 5.4.3 Boundary Fields; 5.4.4 Enhanced Backscattering Effect; 5.4.5 Loss Mechanism.
  • 5.4.6 Probability Distribution Functions5.5 Figures of Merit; 5.5.1 Field Uniformity; 5.5.2 Lowest Usable Frequency; 5.5.3 Correlation Coefficient and Independent Sample Number; 5.5.4 Field Anisotropy Coefficients and Inhomogeneity Coefficients; 5.5.5 Stirring Ratio; 5.5.6 K-Factor; 5.6 Summary; References; Chapter 6 The Design of a Reverberation Chamber; 6.1 Introduction; 6.2 Design Guidelines; 6.2.1 The Shape of the RC; 6.2.2 The Lowest Usable Frequency; 6.2.3 The Working Volume; 6.2.4 The Q Factor; 6.2.5 The Stirrer Design; 6.3 Simulation of the RC; 6.3.1 Monte Carlo Method.
  • 6.3.2 Time Domain Simulation6.3.3 Frequency Domain Simulation; 6.4 Time Domain Characterisation of the RC; 6.4.1 Statistical Behaviour in the Time Domain; 6.4.2 Stirrer Efficiency Based on Total Scattering Cross Section; 6.4.3 Time-Gating Technique; 6.5 Duality Principle in the RC; 6.6 The Limit of ACS and TSCS; 6.7 Design Example; 6.8 Summary; References; Chapter 7 Applications in the Reverberation Chamber; 7.1 Introduction; 7.2 Q Factor and Decay Constant; 7.3 Radiated Immunity Test; 7.4 Radiated Emission Measurement; 7.5 Free-Space Antenna S-Parameter Measurement.

Ejemplares similares