DocumentCode :
1168584
Title :
On the Passivity and Stability of Propagating Electromagnetic Waves
Author :
Wohlers, Martin Ronald
Volume :
18
Issue :
3
fYear :
1971
fDate :
5/1/1971 12:00:00 AM
Firstpage :
332
Lastpage :
336
Abstract :
We consider the uniform transmission line network that represents electromagnetic waves, with propagation constants 
and characteristic impedances 
( 
is the complex frequency variable), that are propagating in uniform homogeneous waveguides. A wave is said to be passive (active) if the net flow of electromagnetic energy associated with it is into (out of) the material through which the wave is propagating. On the other hand, a wave is stable if it does not grow, either spatially or temporally, as it propagates. It is shown that in order for a wave to be passive it is necessary that be analytic, be analytic and nonzero, ![[\\Re k(p)] {\\Re [1/Z(p)]} \\geq O, Z(p^{\\ast })=Z^{\\ast }(p)](/images/tex/10928.gif)
, and 
, all in 
. In the special case where 
, we prove that the passivity conditions guarantee that 
and ![\\Re [k(p)/p] \\neq O](/images/tex/10933.gif)
in , which enables us to demonstrate that a passive wave is in fact stable, even though a stable wave may be active. We also develop an algebraic test to determine if any roots of a polynomial in 
(the socalled dispersion equation) are propagation constants of active waves.
and characteristic impedances ( is the complex frequency variable), that are propagating in uniform homogeneous waveguides. A wave is said to be passive (active) if the net flow of electromagnetic energy associated with it is into (out of) the material through which the wave is propagating. On the other hand, a wave is stable if it does not grow, either spatially or temporally, as it propagates. It is shown that in order for a wave to be passive it is necessary that be analytic, be analytic and nonzero, , and , all in . In the special case where , we prove that the passivity conditions guarantee that and in , which enables us to demonstrate that a passive wave is in fact stable, even though a stable wave may be active. We also develop an algebraic test to determine if any roots of a polynomial in (the socalled dispersion equation) are propagation constants of active waves.Keywords :
Distributed networks; General circuit theory; Guided electromagnetic waves; Network theory; Stability; Electromagnetic propagation; Electromagnetic scattering; Electromagnetic waveguides; Frequency; Impedance; Polynomials; Propagation constant; Stability; Testing; Transmission lines;
fLanguage :
English
Journal_Title :
Circuit Theory, IEEE Transactions on
Publisher :
ieee
ISSN :
0018-9324
Type :
jour
DOI :
10.1109/TCT.1971.1083287
Filename :
1083287
Link To Document :
