An update on the circuit approach to calculate shielding effectiveness

The shielding effectiveness of an enclosure at low frequencies can be computed using a circuit approach. Not only does this technique include the effects of the properties of the shield material, but it also includes the details of the geometry of the enclosure. This approach allows a nonempirical c...

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Bibliographic Details
Published inIEEE transactions on electromagnetic compatibility Vol. 30; no. 3; pp. 211 - 221
Main Author Bridges, J.E.
Format Journal Article
LanguageEnglish
Published New York, NY IEEE 01.08.1988
Institute of Electrical and Electronics Engineers
Subjects
Applied sciences
Bridge circuits
Current distribution
Dipole antennas
Distributed parameter circuits
Electromagnetic compatibility
Electromagnetic shielding
Equations
Exact sciences and technology
Geometry
Information, signal and communications theory
Magnetic circuits
Magnetic shielding
Telecommunications and information theory
Transmission line theory
Electromagnetic compatibility
Shielding
Enclosure
Electromagnetic shielding
Dipole antenna
Loop antenna
Circuit theory
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Summary:The shielding effectiveness of an enclosure at low frequencies can be computed using a circuit approach. Not only does this technique include the effects of the properties of the shield material, but it also includes the details of the geometry of the enclosure. This approach allows a nonempirical consideration of mesh enclosures and the effects of resistive seams in enclosure walls. By working with the circuit analogue, penetration by transient fields can be computed. Essentially the enclosure is viewed as an antenna. In the case of magnetic shielding effectiveness, the enclosure is viewed as a short-circuited loop antenna. In the case of electric-field penetration, the enclosure is viewed as a fat electric dipole. Using this characterization and exact solutions where available, the current distribution on the outside of the enclosure is determined. Based on the current distribution, the penetrating fields are computed. The equations are developed in such a way as to preserve a lumped circuit analogue for the low-frequency region. The basic circuit equations for magnetic field penetration are rederived from a rigorous solution. Rules to estimate the rise time, fall time, and peak magnitudes of transient penetrating fields are developed. The electric shielding effectiveness is developed in a similar manner.< >
Bibliography:ObjectType-Article-2
SourceType-Scholarly Journals-1
ObjectType-Feature-1
content type line 23
ISSN:0018-9375
1558-187X
DOI:10.1109/15.3299