Key focus: Briefly look at linear antennas and various dipole antennas and plot the normalized power gain pattern in polar plot and three dimensional plot.
Linear antennas
Linear antennas are electrically thin antennas whose conductor diameter is very small compared to the wavelength of the radiation λ.
Viewed in a spherical coordinate system (Figure 1), for linear antenna, the antenna is oriented along the z-axis such that the radiation vector has only components along directions of the radial distance Fr and the polar angle Fθ. The radiation vector is determined by the current density J which is characterized by the current distribution I(z) [1].
Hertzian dipole (infinitesimally small dipole)
Hertzian dipole is the simplest configuration of a linear antenna used for study purposes. It is an infinitesimally small (typically
The radiation vector Fz (θ) is given by [1]
The normalized power gain of the Hertzian dipole is [2]
where, C0 is a constant chosen to make maximum of g(θ) equal to unity and θ is the polar angle in the spherical coordinate system.
Center-fed dipole (standing wave antenna)
For the center-fed small dipole antenna, the current distribution is assumed to be a standing wave. Defining k = 2π/λ as the wave number and h = L/2 as the half-length of the antenna, the current distribution and the normalized power gain g(θ) are given by
where, Cn is a constant chosen to make maximum of g(θ) equal to unity and θ is the polar angle in the spherical coordinate system.
For half-wave dipole, set L = λ/2 or kl = π. Therefore, the current distribution for half-wave dipole shrinks to
The normalized power gain is
Plotting the normalized power gain
Let’s plot the normalized power gain pattern of Hertzian & Half-wave dipole antennas in polar plot and three dimensional plot.
Check out my Google colab for the python code to plot the normalized power gain in polar plot as well as three dimensional plot. The results are given below.
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References
[1] Orfanidis, S.J. (2013) Electromagnetic Waves and Antennas, Rutgers University. https://www.ece.rutgers.edu/~orfanidi/ewa/
[2] Constantine A. Balanis, Antenna Theory: Analysis and Design, ISBN: 978-1118642061, Wiley; 4th edition (February 1, 2016)