Introduction To Modern Planar Transmission Lines. Anand K. Verma

Introduction To Modern Planar Transmission Lines - Anand K. Verma


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target="_blank" rel="nofollow" href="#ulink_20cb2111-c0dc-59b2-84f7-d2d62b4bb3ff">(4.4.9)equation

      (4.4.10)equation

      In the case of an external source‐free homogeneous isotropic medium, Maxwell’s equations are written in terms of field intensities only:

      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 images over the surface S. Its boundary is enclosed by the perimeter C. Stoke theorem is defined with respect to Fig. (4.8b) and Gauss divergence theorem with respect to Fig. (4.8c). The unit vector images shows the direction of a normal to the surface S. Figure (4.8c) shows a vector images existing in the whole of the volume V that is enclosed by the surface S.

      Maxwell’s equations in the integral form, for images=0, are obtained by taking the surface integral of Maxwell’s equation (4.4.1a):

      (4.4.15)equation

      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)equation

      Likewise, using Maxwell’s equation (4.4.1b) and (4.4.12) for images=0, the second Maxwell’s equation is written in the integral form, giving the modified Ampere’s law:

      (4.4.17)equation

      In the above equation, Jc and Jd are conduction and displacement current densities creating the magnetic field images. The above expression is generalized Ampere’s law due to Maxwell. The magnetomotive force, mmf, is obtained as follows:

      4.4.2 Power and Energy Relation from Maxwell Equations

      The external power, supplied by the source to the medium, is

      (4.4.19)equation

      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 images are normal to each other. The power density Скачать книгу