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Electromagnetic Anechoic Chambers: A Fundamental Design and Specification Guide

Electromagnetic Anechoic Chambers: A Fundamental Design and Specification Guide

Leland H. Hemming

ISBN: 978-0-471-20810-5

Jul 2002, Wiley-IEEE Press

248 pages

Select type: Hardcover

In Stock



A practical one-volume guide to anechoic chamber designs for electromagnetic measurements

The electromagnetic anechoic chamber has been with us since it was invented at the Naval Research Laboratory in Washington, DC, in the early 1950s. Just about every major aerospace company has large numbers of them located throughout the United States and the world. Now, because of the stringent electromagnetic interference requirements that must be considered in the development of all new electronic products, these facilities are appearing in the automotive, telecommunications, aerospace, computer, and other industries.

This handbook provides the designer/procurer of electromagnetic chambers with a single source of practical information on the full range of anechoic chamber designs. It reviews the current state of the art in indoor electromagnetic testing facilities and their design and specifications. You'll find information on a large variety of anechoic chambers used for a broad range of electromagnetic measurements that are commonly conducted in indoor test facilities as well as details on:
* Measurement theory to support the chamber design procedures provided in each of the specific chamber designs
* Test facilities for the measurement of antennas, scattering (RCS), and electromagnetic compatibility
* An extensive set of photographs, including a special color section highlighting some of the more interesting anechoic test facilities that have been built to solve various measurement problems
* Design/procurement checklists


1 Introduction.

1.1 The Text Organization.


2 Measurement Principles Pertaining to Anechoic Chamber Design.

2.1 Introduction.

2.2 Measurement of Electromagnetic Fields.

2.2.1 Introduction.

2.2.2 Antennas.

2.2.3 Radiated Emissions.

2.2.4 Radiated Susceptibility.

2.2.5 Military Electromagnetic Compatibility.

2.2.6 Antenna System Isolation.

2.2.7 Radar Cross Section.

2.3 Free-Space Test Requirements.

2.3.1 Introduction.

2.3.2 Phase.

2.3.3 Amplitude.

2.3.4 Polarization.

2.3.5 The Friis Transmission Formula.

2.4 Supporting Measurement Concepts.

2.4.1 Introduction.

2.4.2 Coordinate Systems and Device Positioners.

2.4.3 Decibels.

2.4.4 Effects of Reflected Energy.

2.4.5 Effects of Antenna Coupling.

2.5 Outdoor Measurement Facilities.

2.5.1 Introduction.

2.5.2 Electromagnetic Design Considerations and Criteria.

2.5.3 Elevated Outdoor Antenna Range.

2.5.4 Ground Reflection Antenna Range.

2.5.5 Open-Area Test Sites (OATS).


3 Electromagnetic Absorbing Materials.

3.1 Introduction.

3.2 Microwave Absorbing Materials.

3.2.1 Pyramidal Absorber.

3.2.2 Wedge Absorber.

3.2.3 Convoluted Microwave Absorber.

3.2.4 Multilayer Dielectric Absorber.

3.2.5 Hybrid Dielectric Absorber.

3.2.6 Walkway Absorber.

3.3 Low-Frequency Absorbing Material.

3.3.1 Introduction.

3.3.2 Ferrite Absorbers.

3.3.3 Hybrid Absorbers.

3.4 Absorber Modeling.

3.5 Absorber Testing.


4 The Chamber Enclosure.

4.1 Introduction.

4.2 Electromagnetic Interference.

4.3 Controlling the Environment.

4.4 Electromagnetic Shielding.

4.4.1 Introduction.

4.4.2 The Welded Shield.

4.4.3 The Clamped Seam or Prefabricated Shield.

4.4.4 The Single-Shield Systems.

4.5 Penetrations.

4.6 Performance Verification.

4.7 Shielded Enclosure Grounding.

4.8 Fire Protection.


5 Anechoic Chamber Design Techniques.

5.1 Introduction.

5.2 Practical Design Procedures.

5.2.1 Introduction.

5.2.2 Quick Estimate of Chamber Performance.

5.2.3 Detailed Ray-Tracing Design Procedure.

5.3 Computer Modeling.

5.3.1 Introduction.

5.3.2 Ray Tracing.

5.3.3 Finite-Difference Time-Domain Model.

5.4 Other Techniques.

5.5 Antennas Used In Anechoic Chambers.

5.5.1 Introduction.

5.5.2 Rectangular Chamber Antennas.

5.5.3 Antennas for Tapered Chambers.

5.5.4 EMI Chambers.


6 The Rectangular Chamber.

6.1 Introduction.

6.2 Antenna Testing.

6.2.1 Introduction.

6.2.2 Design Considerations.

6.2.3 Design Example.

6.2.4 Acceptance Test Procedures.

6.3 Radar Cross-Section Testing.

6.3.1 Design Considerations.

6.3.2 Design Example.

6.3.3 Acceptance Test Procedures.

6.4 Near-Field Testing.

6.4.1 Introduction.

6.4.2 Chamber Design Considerations.

6.4.3 Design Example.

6.4.4 Acceptance Test Procedure.

6.5 Electromagnetic Compatibility Testing.

6.5.1 Introduction.

6.5.2 Chamber Design Considerations.

6.5.3 Design Examples.

6.5.4 Acceptance Test Procedures.

6.6 Immunity Testing.

6.6.1 Introduction.

6.6.2 Mode-Stirred Test Facility.

6.7 EM System Compatibility Testing.

6.7.1 Design Considerations.

6.7.2 Acceptance Testing.


7 The Compact Range Chamber.

7.1 Introduction.

7.2 Antenna Testing.

7.2.1 Prime Focus Compact Range.

7.2.2 Dual Reflector Compact Range.

7.2.3 Shaped Reflector Compact Range.

7.2.4 Compact Antenna Range Absorber Layout.

7.2.5 Acceptance Testing of the Compact Antenna Anechoic Chamber.

7.3 Compact RCS Ranges.

7.3.1 Introduction.

7.3.2 Design Example.

7.3.3 Acceptance Testing.


8 Incorporating Geometry in Anechoic Chamber Design.

8.1 Introduction.

8.2 The Tapered Chamber.

8.2.1 Introduction.

8.2.2 Antenna Testing.

8.2.3 Radar Cross-Section Measurements.

8.3 The Double Horn Chamber.

8.3.1 Introduction.

8.3.2 Antenna Testing.

8.3.3 Emissions and Immunity Testing.

8.4 The Missile Hardware-in-the-Loop Chamber.

8.4.1 Introduction.

8.4.2 Design Considerations.

8.4.3 Design Example.

8.4.4 Acceptance Test Procedures.

8.5 Consolidated Facilities.

8.5.1 Introduction.

8.5.2 Design Considerations.

8.5.3 Design Examples.

8.5.4 Acceptance Test Procedures.

8.6 The TEM Cell.

8.6.1 Introduction.

8.6.2 TEM Principles of Operation.

8.6.3 Typical Performance.


9 Test Procedures.

9.1 Introduction.

9.2 Absorber Testing.

9.2.1 Introduction.

9.2.2 Testing of Microwave Absorber.

9.2.3 Low-Frequency Testing.

9.2.4 Compact Range Reflector Testing.

9.2.5 Fire-Retardant Testing.

9.3 Microwave Anechoic Chamber Test Procedures.

9.3.1 Introduction.

9.3.2 Free-Space VSWR Method.

9.3.3 Pattern Comparison Method.

9.3.4 X–Y Scanner Method.

9.3.5 RCS Chamber Evaluation.

9.4 EMC Chamber Acceptance Test Procedures.

9.4.1 Introduction.

9.4.2 Volumetric Site Attenuation.

9.4.3 Field Uniformity.

9.5 Shielding Effectiveness.


10 Examples of Indoor Electromagnetic Test Facilities.

10.1 Introduction.

10.2 Antenna Testing.

10.2.1 Introduction.

10.2.2 Rectangular Test Chamber.

10.2.3 Tapered Anechoic Chamber.

10.2.4 Compact Range Test Chamber.

10.2.5 Near-Field Test Chamber.

10.3 Radar Cross-Section Testing.

10.3.1 Introduction.

10.3.2 Compact Range Radar Cross-Section Facilities.

10.4 EMC Test Chambers.

10.4.1 Introduction.

10.4.2 Emission Test Chambers.

10.5 Electromagnetic System Compatibility Testing.

10.5.1 Introduction.

10.5.2 Aircraft Systems.

10.5.3 Spacecraft Test Facilities.


Appendix A: Procedure for Determining the Area of Specular Absorber Treatment.

A.1 Introduction.

A.2 Fresnel Zone Analysis.

Appendix B :Test Region Amplitude Taper.

B.1 Introduction.

B.2 Antenna Data.

Appendix C: Design/Specification Checklists.

C.1 Introduction.

C.2 The Rectangular Chamber.

C.2.1 Introduction.

C.2.2 Antenna Testing.

C.2.3 RCS Testing.

C.2.4 Near-Field Testing.

C.2.5 EMI Testing.

C.2.6 Isolation Testing.

C.2.7 Impedance Testing.

C.3 Compact Range.

C.3.1 Introduction.

C.3.2 Antenna/Radome Testing.

C.3.3 RCS Testing.

C.4 Shaped Chambers.

C.4.1 Introduction

C.4.2 Tapered Chamber.

C.4.3 Double Horn Chamber.

C.4.4 Hardware-in-the-Loop Testing.

C.5 Shielding Design Checklist.

C.5.1 Introduction.

C.5.2 Checklist for Prefabricated Shielding.

C.5.3 Checklist for Welded Enclosures.

C.5.4 Checklist for Architectural Shielding.

C.5.5 Conventional Construction.

C.5.6 Fire Protection.



Selected Bibliography.


About the Author.

""...a comprehensive, thorough text...that will not sit on the is a text that will be referenced often by those individuals committed to ensuring?the highest quality of test results."" (IEEE Instrumentation & Measurement Magazine, March 2003)