Array factor: Difference between revisions

Latest revision as of 10:01, 22 May 2026

Short description: Function in the theory of antennas

In the study of antennas, the array factor is a mathematical function that describes the signal of an antenna array as a combination of the signals of its individual antennas. More precisely, the array factor is multiplied by the radiation pattern of an individual antenna to produce the pattern of the entire array. This difference in the patterns is due to the constructive and destructive interference properties of radio waves.

The array factor depends on

the positions of the individual antennas in the array,
the complex weights (amplitudes and phases) being used to combine (or excite) the signals of the antennas, and
the direction of signal arrival (or transmission).

When the antenna weights are chosen appropriately, then the array factor has large magnitude for signals in the desired direction(s) and small in the direction(s) that the array operator wants to ignore. This is how the beam of a phased array is steered.

Calculation

In order to simplify the mathematics, a number of assumptions are typically made:

All antennas are identical in every respect.
The antennas are uniformly spaced.
The signal phase shift between radiators is constant.

The array factor $A F$ is the complex-valued far-field radiation pattern obtained for an array of $N$ isotropic radiators located at coordinates ${\vec{r}}_{n}$ , as determined by:^[1]

$A F (\hat{r}) = \sum_{n = 1}^{N} a_{n} e^{j k \hat{r} \cdot {\vec{r}}_{n}},$

where $a_{n}$ are the complex-valued excitation coefficients, and $\hat{r}$ is the direction unit vector. The array factor is defined in the transmitting mode,^[2] with the time convention $e^{j ω t}$ . A corresponding expression can be derived for the receiving mode, where a negative sign appears in the exponential factors, as derived in reference.^[3]

References

↑ Balanis, C. A.. Antenna Theory, Analysis and Design (3 ed.). p. 291.
↑ "IEEE Standard for definitions of terms for antennas". IEEE STD. 2014.
↑ Frid, Henrik (2020). Analysis and Optimization of Installed Antenna Performance. Stockholm, Sweden: KTH (PhD thesis). pp. 36–39. ISBN 978-91-7873-447-4. http://kth.diva-portal.org/smash/record.jsf?pid=diva2%3A1392934&dswid=5174.

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-An array is simply a group of objects, and the array factor is a measure of how much a specific characteristic changes because of the grouping. This phenomenon is observed when antennas are grouped together. The radiation (or reception) pattern of the antenna group is considerably different from that of a single antenna. This is due to the constructive and destructive interference properties of radio waves. A well designed antenna array, allows the broadcast power to be directed to where it is needed most.
+{{Short description|Function in the theory of antennas}}
+{{technical|date=January 2019}}
+In the study of [[Engineering:Antenna (radio)|antennas]], the '''array factor''' is a mathematical function that describes the signal of an [[Physics:Antenna array|antenna array]] as a combination of the signals of its individual antennas.
+More precisely, the array factor is multiplied by the [[Engineering:Radiation pattern|radiation pattern]] of an individual antenna to produce the pattern of the entire array.
+This difference in the patterns is due to the constructive and destructive interference properties of radio waves.
-These antenna arrays are typically one dimensional, as seen on collinear dipole arrays, or two dimensional as on military phased arrays.
+The array factor depends on
+* the positions of the individual antennas in the array,
+* the complex weights (amplitudes and phases) being used to combine (or excite) the signals of the antennas, and
+* the direction of signal arrival (or transmission).
+When the antenna weights are chosen appropriately, then the array factor has large magnitude for signals in the desired direction(s) and small in the direction(s) that the array operator wants to ignore.
+This is how the beam of a [[Engineering:Phased array|phased array]] is steered.
+==Calculation==
 In order to simplify the mathematics, a number of assumptions are typically made:
-. all radiators are equal in every respect
+# All antennas are identical in every respect.
-. all radiators are uniformly spaced
+# The antennas are uniformly spaced.
-. the signal phase shift between radiators is constant.
+# The signal phase shift between radiators is constant.
-The array factor <math> AF </math> is the complex-valued far-field [[Engineering:Radiation pattern|radiation pattern]] obtained for an array of <math> N </math> isotropic radiators located at coordinates <math> \vec{r}_n </math>, as determined by:<ref>{{cite book |last1=Balanis |first1=C. A. |title=Antenna Theory, Analysis and Design |page=291 |edition=3}}</ref>
+The array factor <math> AF </math> is the complex-valued far-field [[Engineering:Radiation pattern|radiation pattern]] obtained for an array of <math> N </math> isotropic radiators located at [[Coordinates|coordinates]] <math> \vec{r}_n </math>, as determined by:<ref>{{cite book |last1=Balanis |first1=C. A. |title=Antenna Theory, Analysis and Design |page=291 |edition=3}}</ref>
 <math> AF(\hat{r}) = \sum_{n=1}^N a_n e^{jk\hat{r}\cdot\vec{r}_n},</math>

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