Introduction To Modern Planar Transmission Lines. Anand K. Verma
target="_blank" rel="nofollow" href="#ulink_20cb2111-c0dc-59b2-84f7-d2d62b4bb3ff">(4.4.9)
where flux density vectors are related to field intensity vectors in an anisotropic medium by the following tensor constitutive relations:
(4.4.10)
In the case of an external source‐free homogeneous isotropic medium, Maxwell’s equations are written in terms of field intensities only:
where the scalar constitutive relations are
The differential form of Maxwell equations does not account for the creation of the fields in the space due to the sources such as the charge or current distributed over a line, surface, or volume. This case is incorporated in Maxwell’s equations by converting them to the integral forms. It is achieved with the help of two vector identities:
Figure (4.8b) shows the existence of a vector
Maxwell’s equations in the integral form, for
It is assumed that a surface enclosing the magnetic field does not change with time. By using equation (4.4.12), equation (4.4.14) is changed in the following form:
(4.4.15)
where ψm is the magnetic flux. It is the Faraday law of induction that gives the induced voltage V, i.e. the emf, on a conducting loop containing the time‐varying magnetic flux, ψm:
(4.4.16)
Likewise, using Maxwell’s equation (4.4.1b) and (4.4.12) for
(4.4.17)
In the above equation, Jc and Jd are conduction and displacement current densities creating the magnetic field
where ψe is the time‐dependent electric flux. Equation (4.4.18b) is Maxwell’s induction law giving the induced mmf due to the time‐varying electric field. For the source free medium with Jc = 0, it is the complementary induction law of Faraday’s law of induction.
4.4.2 Power and Energy Relation from Maxwell Equations
A medium supporting the electromagnetic fields also stores the EM‐energy and supports the power flow. The EM‐power is supplied to the enclosure by the time‐dependent external electric current density Jext and the time‐dependent external magnetic current density Mext. They create the time‐dependent electric field (
The external power, supplied by the source to the medium, is
(4.4.19)
The field and source quantities have RMS values, and these are also time‐dependent. The power on a transmission line, carrying the voltage and current wave, is P = VI cos φ, i.e. a scalar product of the voltage and current. The EM‐wave is a transverse electromagnetic wave, where the fields