Antennas. Yi Huang

Antennas - Yi Huang


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      where

       ρ is the charge density.

        is a vector operator;

       ∇× is the curl operator or called rot in some countries instead of curl.

       ∇• is the divergence operator.

      Here we have both the vector cross product and the dot product.

Photo depicts James Clerk Maxwell

      Now let us have a closer look at these mathematical equations to see what they really mean in terms of the physical explanations.

      1.4.3.1 Faraday's Law of Induction

      (1.30)equation

      This equation simply means that the induced electromotive force (EMF with a unit in V, it is the left‐hand size of the equation expressed in the integral form as shown in Equation (1.37)) is proportional to the rate of change of the magnetic flux. In layman's terms, moving a conductor (such as a metal wire) through a magnetic field produces a voltage. The resulting voltage is directly proportional to the speed of movement. It is apparent from this equation that a time‐varying magnetic field images will generate an electric field, i.e. E ≠ 0. But if the magnetic field is not time varying, it will NOT generate an electric field!

      1.4.3.2 Amperes’ Circuital Law

      (1.31)equation

      This equation shows that both the current (J) and time‐varying electric field images can generate a magnetic field, i.e. H ≠ 0.

      1.4.3.3 Gauss' Law for Electric Field

      (1.32)equation

      This is the electrostatic application of Gauss's generalized theorem, giving the equivalence relation between any flux, e.g. of liquids, electric or gravitational, flowing out of any closed surface and the result of inner sources and sinks, such as electric charges or masses enclosed within the closed surface. As a result, it is not possible for electric fields to form a closed loop. Since D = εE, it is also clear that charges (ρ) can generate electric fields, i.e. E ≠ 0.

      1.4.3.4 Gauss’ Law for Magnetic Field

      (1.33)equation

      This shows that the divergence of the magnetic field (∇ • B) is always zero, which means that the magnetic field lines are closed loops, thus the integral of B over a closed surface is zero.

      For a time‐harmonic EM field (which means the field linked to the time by factor ejωt where ω is the angular frequency and t is the time), we can use the constitutive relations

      (1.34)equation

      to write Maxwell’s equations into the following forms

      where B and D are replaced by the electric field E and magnetic field H to simplify the equations and they will not appear again unless necessary.

      (1.36)equation

      It is hard to predict how the loss tangent changes with the frequency since both the permittivity and conductivity are functions of frequency as well. More discussion will be given in Chapter 3.

      1.4.4 Boundary Conditions

      Maxwell’s equations can also be written in the integral form as

      (1.38)equation

      where images is the surface unit vector from Medium 2 to Medium 1 as shown in Figure 1.14. This condition means that the tangential components of an electric field (images) are continuous across the boundary between any two media.