Antenna factor

Antennas
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In telecommunications, the antenna factor is defined as the ratio of the electric field strength to the voltage V (units: V or µV) induced across the terminals of a antenna.

For an electric field antenna, the field strength is in units of V/m or µV/m and the resulting antenna factor AF is in units of 1/m:

AF = \frac EV

If all quantities are expressed logarithmically in decibels instead of SI units, the above equation becomes

AF_{\mathrm{dBm}^{-1}} = E_\mathrm{\mathrm{dBV/m}} - V_{\mathrm{dBV}} = E_\mathrm{\mathrm{dB}\mu\mathrm{V/m}} - V_{\mathrm{dB}\mu\mathrm{V}}

For a magnetic field antenna, the field strength is in units of A/m and the resulting antenna factor is in units of A/(Vm). For the relationship between the electric and magnetic fields, see the impedance of free space.

In a 50 Ω system, the antenna factor is related to the antenna gain G and the wavelength λ via:

AF = \frac{9.73}{\lambda \sqrt{G} }

The variable G means antenna gain (dimensionless) and it can be written in terms of effective aperture A to obtain the final expression considering the impedance of free space (376.7Ω) and the load as 50Ω. The antenna effective aperture can be written as A = (λ²G)/4π.

References

Interpreting Antenna Performance Parameters for EMC Applications
Interpreting Antenna Performance Parameters for EMC Applications An excellent page with summaries of all the relevant equations
Antenna Theory