In this work, we revisit the theory of stochastic elec
tromagnetic fields using exterior differential forms. We
present a short overview as well as a brief introdu
ction to the application of differential forms in
electromagnetic theory.
A differential form is in principle a quantity, which can be integrated. For the case of a three-dimensional
space, the domains of integration could either
be lines (1D), areas (2D) or volumes (3D). The
corresponding differential forms are then given as one-forms, two-forms and three-forms. We describe
electric-, and magnetic fields by differential one-forms
while electric-, and magnetic displacement fields
are given by two-forms. Since charge density is a q
uantity that is given as a
density in space, we use
pseudo scalars, or differential three-forms to des
cribe it. A well-known result from the field of
mathematics, the lemma of Poincaré, can then be used
to ensure the existence of a field, just by the
presence of some charge density. Probably the most
important advantage, which
makes exterior calculus
superior to vectors, when considering electromagneti
c fields, is that the formalism becomes completely
independent of the choice of
a specific coordinate system.
Within the framework of exterior calculus, we deri
ve equations for the second order moments, describing
stochastic electromagnetic fields. Also the equations
for the double one-forms, or two-forms respectively,
relating the second order moments are independent fo
r the choice of a particular basis. Since the
resulting objects are continuous quantities in sp
ace, a discretization sc
heme based on the Method of
Moments (MoM) is introduced for numerical treatment.
The MoM is applied in such a way, that the notation of
exterior calculus is maintained while we still arrive
at the same set of algebraic equat
ions in the end, we would have obtained when formulating the theory
using the traditional notation of vector calculus. Fo
r properly setting up the Method of Moments, we
introduce an inner product for differential forms. We show that our inner product is valid by exploring
some important properties, like sesquilinearity and positive semi-definiteness.
We conclude our work with an analytic calculation
of the propagation of correlations of two Hertzian
dipoles using the formalism of exterior calculus.
We see that even though we consider uncorrelated
sources, the cross-correlati
on spectra of the excited elec
tric field are non-vanishing.
«
In this work, we revisit the theory of stochastic elec
tromagnetic fields using exterior differential forms. We
present a short overview as well as a brief introdu
ction to the application of differential forms in
electromagnetic theory.
A differential form is in principle a quantity, which can be integrated. For the case of a three-dimensional
space, the domains of integration could either
be lines (1D), areas (2D) or volumes (3D). The
correspondin...
»
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