# Antenna Theory – Radiation Pattern

Radiation is the term used to represent the emission or reception of wave front at the antenna, specifying its strength. In any illustration, the sketch drawn to represent the radiation of an antenna is itsÂ radiation pattern. One can simply understand the function and directivity of an antenna by having a look at its radiation pattern.

The power when radiated from the antenna has its effect in the near and far field regions.

• Graphically, radiation can be plotted as a function ofÂ angular positionÂ andÂ radial distanceÂ from the antenna.
• This is a mathematical function of radiation properties of the antenna represented as a function of spherical co-ordinates, E (Î¸, Ã˜) and H (Î¸, Ã˜).

The energy radiated by an antenna is represented by theÂ Radiation patternÂ of the antenna. Radiation Patterns are diagrammatical representations of the distribution of radiated energy into space, as a function of direction.

Let us look at the pattern of energy radiation.

The figure given above shows radiation pattern of a dipole antenna. The energy being radiated is represented by the patterns drawn in a particular direction. The arrows represent directions of radiation.

The radiation patterns can be field patterns or power patterns.

• TheÂ field patternsÂ are plotted as a function of electric and magnetic fields. They are plotted on logarithmic scale.
• TheÂ power patternsÂ are plotted as a function of square of the magnitude of electric and magnetic fields. They are plotted on logarithmic or commonly on dB scale.

The radiation pattern is a three-dimensional figure and represented in spherical coordinates (r, Î¸, Î¦) assuming its origin at the center of spherical coordinate system. It looks like the following figure âˆ’

The given figure is a three dimensional radiation pattern for anÂ Omni directional pattern. This clearly indicates the three co-ordinates (x, y, z).

Two-dimensional pattern can be obtained from three-dimensional pattern by dividing it into horizontal and vertical planes. These resultant patterns are known asÂ Horizontal patternÂ andÂ Vertical patternÂ respectively.

The figures show the Omni directional radiation pattern in H and V planes as explained above. H-plane represents the Horizontal pattern, whereas V-plane represents the Vertical pattern.

### Lobe Formation

In the representation of radiation pattern, we often come across different shapes, which indicate the major and minor radiation areas, by which theÂ radiation efficiencyÂ of the antenna is known.

To have a better understanding, consider the following figure, which represents the radiation pattern of a dipole antenna.

Here, the radiation pattern has main lobe, side lobes and back lobe.

• The major part of the radiated field, which covers a larger area, is theÂ main lobeÂ orÂ major lobe. This is the portion where maximum radiated energy exists. The direction of this lobe indicates the directivity of the antenna.
• The other parts of the pattern where the radiation is distributed side wards are known asÂ side lobesÂ orÂ minor lobes. These are the areas where the power is wasted.
• There is other lobe, which is exactly opposite to the direction of main lobe. It is known asÂ back lobe, which is also a minor lobe. A considerable amount of energy is wasted even here.

### Example

If the antennas used in radar systems produce side lobes, target tracing becomes very difficult. This is because, false targets are indicated by these side lobes. It is messy to trace out the real ones and to identify the fake ones. Hence,Â eliminationÂ of theseÂ side lobesÂ is must, in order to improve the performance and save the energy.

### Remedy

The radiated energy, which is being wasted in such forms needs to be utilized. If these minor lobes are eliminated and this energy is diverted into one direction (that is towards the major lobe), then theÂ directivityÂ of the antenna gets increased which leads to antennaâ€™s better performance.