Let's get right down to the study of antennas and Antenna Basics. Suppose one day you're walking down the street and a kind but impatient person runs up and asks you to design an antenna for them. "Sure", you quickly reply, adding "what is the desired frequency, gain, bandwidth, impedance, and polarization?"
Or perhaps you have never heard of (or are a little rusty) on the above parameters. Well then, you've come to the right place. Before we can design an antenna or discuss antenna types, we must understand the basics of antennas, which are the fundamental parameters that characterize an antenna.
So let us learn something. We'll start with frequency and step through radiation patterns, directivity and gain, and ultimately close with an explanation on why antennas radiate. Jump ahead if this is already familiar to you.
The basics of sinusoids (sine and cosine waves), wavelength, frequency and the speed of light.
A discussion on how all waveforms in the universe are made up of the sum of sinusoids (simple waves) helps explains why in antenna theory we always discuss wavelength and frequency no matter what signal (information) we want to transmit.
No discussion on antenna fundamentals is complete without a real-world list of frequency bands.
The radiation pattern for an antenna is defined on this page. We have 3D graphs of real antenna radiation patterns, with a discussion on isotropic, omnidirectional and directional radiation patterns. Radiation patterns are of the utmost importance in the discussion of antenna basics.
The introduction to antennas continues with a discussion of Field Regions. The Far Field, Near Field and Fresnel Regions for an antenna are presented.
Directivity is fundamental to antennas. It is a measure of how "directional" an antenna's radiation pattern is.
An antenna's efficiency is a measure of how much power is radiated by the antenna relative to the antenna input power.
Antenna Gain is a measure of power radiated in a particular direction (typically the peak direction of radiation).
An antenna's radiation pattern in the far-field is often characterized by its beamwidth and sidelobe levels. This introduction to antennas illustrates this with an example.
Antenna Impedance is presented as the ratio of voltage to current at the antenna's terminals. Low- and High-Frequency models are presented for transmission lines. The fundamentals of antenna theory require that the antenna be "impedance matched" to the transmission line or the antenna will not radiate. The concept of VSWR is introduced as a measure of how well matched an antenna is.
The bandwidth of an antenna is the frequency range over which the antenna radiates. The bandwidth can be defined in different ways; this page presents an introduction to antenna bandwidth.
All electromagnetic plane waves have an associated polarization. The antenna concepts of Linear, Circular and elliptical polarization are presented.
Polarization of Antennas
Antennas are also classified by their polarization; this defines the type of plane wave polarization the antenna is most sensitive to. This is a fundamental antenna concept.