Introduction To Modern Planar Transmission Lines. Anand K. Verma

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      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 images is defined by a vector product of images, known as the Poynting vector:

      The divergence of the above equation provides the power entering, or leaving, a location in the space:

      The energy contained per unit volume, i.e. the energy density, in a dispersive and a nondispersive medium, in the form of the electric and magnetic energy, is given by the following expressions:

      (4.4.23)equation

      The medium having finite conductivity σ dissipates the EM‐energy in the form of heat given by the Joule's law:

      (4.4.24)equation

      The total power carried in a medium, in the form of the EM‐wave, is

      (4.4.25)equation

      The integration is carried over the cross‐section of the medium carrying the EM‐power. The total energy stored in volume V is

      (4.4.26)equation

      The total power dissipated in volume V of the medium is

      (4.4.27)equation

      Thus, power (Pext) supplied by the external source is balanced by the following equation:

      The dot product of equation (4.4.1a) is taken with images, and the dot product of equation (4.4.1b) with images, and subtract one from another to get the following expression:

      (4.4.29)equation

      (4.4.30)equation

      (4.4.31)equation

      The power supplied by the external sources is positive. So, the total power in a medium is negative. Out of the total power supplied to a medium, Pwave is power carried away by the EM‐wave, Pdis is power loss in the medium due to the finite conductivity of the medium, and images is the oscillating electric and magnetic energy in the medium.

      Maxwell’s coupled vector differential equations (4.4.1a) and (4.4.1b) are solved in an external source‐free medium with images to obtain separate wave equations for the electric and magnetic fields. It is like getting the voltage and current wave equations on a transmission line. Maxwell equations are further presented in the vector algebraic form. The present section is concerned with the uniform 1D wave propagation in an unbounded isotropic dielectric medium, also in a conducting medium. The EM‐wave propagation in the anisotropic medium is discussed in section (4.7).

      4.5.1 EM‐wave Equation

      Maxwell’s coupled equations (4.4.1), in the external source‐free medium images, are solved, using the rule of vector algebra, for the electric field intensity images by substituting images from equation (4.4.1b) to equation (4.4.1a):

      (4.5.1)equation

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