Title :
On determining the maximum emissions from electrically large sources
Author :
Wilson, Perry F. ; Hill, David A. ; Holloway, Christopher L.
Author_Institution :
Nat. Inst. of Stand. & Technol., Boulder, CO, USA
fDate :
2/1/2002 12:00:00 AM
Abstract :
This paper examines the use of measurements of the total radiated power from an arbitrary source, combined with theory-based estimates of directivity or quality factor, to accurately predict the maximum electric field radiated by the source either at a line-of-sight distance or in a resonant volume. The approach using total radiated power avoids source rotations during testing and is an efficient alternative to current emission test methods. Examples of simulated (random source set) and measured (box with holes) planar-cut radiation-patterns for electrically large sources are presented. Both simulated and measured data agree well with theoretical estimates
Keywords :
Monte Carlo methods; Q-factor; electric field measurement; electromagnetic compatibility; electromagnetic coupling; electromagnetic interference; magnetic field measurement; resonance; EMC measurement; EMI coupling; Monte Carlo simulation; Q; box; directivity statistics; electrically large sources; electromagnetic compatibility; electromagnetic interference; emission test methods; equipment under test; holes; line-of-sight distance; maximum emissions; maximum radiated electric field; planar-cut radiation-patterns; pseudo-arbitrary EUT; quality factor; random source set; resonant volume; simulated data; simulation model; total radiated power measurement; Electric variables measurement; Electromagnetic compatibility; Electromagnetic measurements; Estimation theory; Frequency; NIST; Q factor; Receiving antennas; Reverberation chamber; Testing;
Journal_Title :
Electromagnetic Compatibility, IEEE Transactions on
