© The Institution of Electrical Engineers
All types of equipment and systems must be designed to meet electromagnetic compatibility (EMC) specifications. To achieve this aim, special design techniques are necessary. Their effective use in practical applications depends on the understanding of the underlying physical principles. EMC problems involve complex electromagnetic interactions and hence can only be tacked effectively by a combination of experimental and numerical tools. In this tutorial the general principles and techniques underlying all EMC design are described
References
-
-
1)
-
G.J. Burke ,
A.J. Poggio
.
(1977)
, Numerical electromagnetic code (NEC) — method of moments.
-
2)
-
C. Christopoulos ,
P. Naylor
.
Coupling between electromagnetic fields and multi-mode transmission systems using transmission-line modelling.
Int. J. Numer. Modell.
,
227 -
240
-
3)
-
C. Christopoulos ,
P.P. Silvester
.
(1990)
, Field analysis software based on the transmission-line modelling method.
-
4)
-
H.W. Ott
.
(1976)
, Noise reduction techniques in electronic systems.
-
5)
-
C. Christopoulos
.
Electromagnetic compatibility. Part 1 General principles.
Power Engineering Journal
,
2 ,
89 -
94
-
6)
-
Anke, D.: `The influence of modern power electronics in EMC', Proc 5th Int. Conf. on Electromagnetic Compatibility, October 1986, York, p. 197–203, IERE Publ. 71.
-
7)
-
R.B. Standler
.
(1989)
, Protection of electronic circuits from overvoltages.
-
8)
-
IEEE guide for the installation of electrical equipment to minimise electrical noise inputs to controllers from external sources IEEE std 518-1982 160 pages.
-
9)
-
Broyde, F.: `Dissipative filters for power electronic applications', Proc. 7th Int. Zürich Symposium on EMC, March 1987, Zürich, p. 393–398.
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