Antenna Theory - End-fire Array

Antenna Theory – End-fire Array

The physical arrangement of end-fire array is same as that of the broad side array. The magnitude of currents in each element is same, but there is a phase difference between these currents. This induction of energy differs in each element, which can be understood by the following diagram.

End-fire Array

The above figure shows the end-fire array in top and side views respectively.

There is no radiation in the right angles to the plane of the array because of cancellation. The first and third elements are fed out of phase and therefore cancel each other’s radiation. Similarly, second and fourth are fed out of phase, to get cancelled.

The usual dipole spacing will be λ/4 or 3λ/4. This arrangement not only helps to avoid the radiation perpendicular to the antenna plane, but also helps the radiated energy get diverted to the direction of radiation of the whole array. Hence, the minor lobes are avoided and the directivity is increased. The beam becomes narrower with the increased elements.

Radiation Pattern

The Radiation pattern of end-fire array is uni-directional. A major lobe occurs at one end, where maximum radiation is present, while the minor lobes represent the losses.

End-fire Radiation

The figure explains the radiation pattern of an end-fire array. Figure 1 is the radiation pattern for a single array, while figures 2, 3, and 4 represent the radiation pattern for multiple arrays.

End-fire Array Vs Broad Side Array

We have studied both the arrays. Let us try to compare the end-fire and broad side arrays, along with their characteristics.

End-fire Broad-side

The figure illustrates the radiation pattern of end-fire array and broad side array.

  • Both, the end fire array and broad side array, are linear and are resonant, as they consist of resonant elements.
  • Due to resonance, both the arrays display narrower beam and high directivity.
  • Both of these arrays are used in transmission purposes.
  • Neither of them is used for reception, because the necessity of covering a range of frequencies is needed for any kind of reception.