Friis transmission equation

Last updated April 16, 2024

The Friis transmission formula is used in telecommunications engineering, equating the power at the terminals of a receive antenna as the product of power density of the incident wave and the effective aperture of the receiving antenna under idealized conditions given another antenna some distance away transmitting a known amount of power.^[1] The formula was presented first by Danish-American radio engineer Harald T. Friis in 1946.^[2] The formula is sometimes referenced as the Friis transmission equation.

Friis' original formula

Friis' original idea behind his transmission formula was to dispense with the usage of directivity or gain when describing antenna performance. In their place is the descriptor of antenna capture area as one of two important parts of the transmission formula that characterizes the behavior of a free-space radio circuit.^[2]

This leads to his published form of his transmission formula:

{\frac {P_{r}}{P_{t}}}=\left({\frac {A_{r}A_{t}}{d^{2}\lambda ^{2}}}\right)

where:

$P_{t}$ is the power fed into the transmitting antenna input terminals;^[2]
$P_{r}$ is the power available at receiving antenna output terminals;^[2]
$A_{r}$ is the effective aperture area of the receiving antenna;^[2]
$A_{t}$ is the effective aperture area of the transmitting antenna;^[2]
$d$ is the distance between antennas;^[2]
$\lambda$ is the wavelength of the radio frequency;^[2]
$P_{t}$ and $P_{r}$ are in the same units of power;^[2]
$A_{r}$ , $A_{t}$ , $d^{2}$ , and $\lambda ^{2}$ are in the same units.^[2]
Distance $d$ large enough to ensure a plane wave front at the receive antenna sufficiently approximated by $d\geq 2a^{2}/\lambda$ where $a$ is the largest linear dimension of either of the antennas.^[2]

Friis stated the advantage of this formula over other formulations is the lack of numerical coefficients to remember, but does require the expression of transmitting antenna performance in terms of power flow per unit area instead of field strength and the expression of receiving antenna performance by its effective area rather than by its power gain or radiation resistance.^[2]

Contemporary formula

Few follow Friis' advice on using antenna effective area to characterize antenna performance over the contemporary use of directivity and gain metrics. Replacing the effective antenna areas with their gain counterparts yields

{\frac {P_{r}}{P_{t}}}=G_{t}G_{r}\left({\frac {\lambda }{4\pi d}}\right)^{2}

where $G_{t}$ and $G_{r}$ are the antenna gains (with respect to an isotropic radiator) of the transmitting and receiving antennas respectively, $\lambda$ is the wavelength representing the effective aperture area of the receiving antenna, and $d$ is the distance separating the antennas.^[1] To use the equation as written, the antenna gains are unitless values, and the units for wavelength ( $\lambda$ ) and distance ( $d$ ) must be the same.

To calculate using decibels, the equation becomes:

P_{r}^{\mathsf {[dB]}}=P_{t}^{\mathsf {[dB]}}+G_{t}^{\mathsf {[dBi]}}+G_{r}^{\mathsf {[dBi]}}+20\log _{10}\left({\frac {\lambda }{4\pi d}}\right)

where:

$P_{t}^{[dB]}$ is the power delivered to the terminals of an isotropic transmit antenna, expressed in dB.^[3]
$P_{r}^{\mathsf {[dB]}}$ is the available power at the receive antenna terminals equal to the product of the power density of the incident wave and the effective aperture area of the receiving antenna proportional to $\lambda ^{2}$ , in dB.^[1]
$G_{t}^{\mathsf {[dBi]}}$ is the gain of the transmitting antenna in the direction of the receiving antenna, in dB.^[1]
$G_{r}^{\mathsf {[dBi]}}$ is the gain of the receiving antenna in the direction of the transmitting antenna, in dB.^[1]

The simple form applies under the following conditions:

$d\gg \lambda$ , so that each antenna is in the far field of the other.^[1]
The antennas are correctly aligned and have the same polarization.^[4]
The antennas are in unobstructed free space, with no multipath propagation.^[4]
The bandwidth is narrow enough that a single value for the wavelength can be used to represent the whole transmission.^[4]
Directivities are both for isotropic radiators (dBi).
Powers are both presented in the same units: either both dBm or both dBW.

The ideal conditions are almost never achieved in ordinary terrestrial communications, due to obstructions, reflections from buildings, and most importantly reflections from the ground. One situation where the equation is reasonably accurate is in satellite communications when there is negligible atmospheric absorption; another situation is in anechoic chambers specifically designed to minimize reflections.^[5]

Derivation

There are several methods to derive the Friis transmission equation. In addition to the usual derivation from antenna theory, the basic equation also can be derived from principles of radiometry and scalar diffraction in a manner that emphasizes physical understanding.^[6] Another derivation is to take the far-field limit of the near-field transmission integral.^[7]

Related Research Articles

In electrical engineering, electrical length is a dimensionless parameter equal to the physical length of an electrical conductor such as a cable or wire, divided by the wavelength of alternating current at a given frequency traveling through the conductor. In other words, it is the length of the conductor measured in wavelengths. It can alternately be expressed as an angle, in radians or degrees, equal to the phase shift the alternating current experiences traveling through the conductor.

In telecommunication, the free-space path loss (FSPL) is the attenuation of radio energy between the feedpoints of two antennas that results from the combination of the receiving antenna's capture area plus the obstacle-free, line-of-sight (LoS) path through free space. The "Standard Definitions of Terms for Antennas", IEEE Std 145-1993, defines free-space loss as "The loss between two isotropic radiators in free space, expressed as a power ratio." It does not include any power loss in the antennas themselves due to imperfections such as resistance. Free-space loss increases with the square of distance between the antennas because the radio waves spread out by the inverse square law and decreases with the square of the wavelength of the radio waves. The FSPL is rarely used standalone, but rather as a part of the Friis transmission formula, which includes the gain of antennas. It is a factor that must be included in the power link budget of a radio communication system, to ensure that sufficient radio power reaches the receiver such that the transmitted signal is received intelligibly.

<span class="mw-page-title-main">Radiation pattern</span> Directional variation in strength of radio waves

In the field of antenna design the term radiation pattern refers to the directional (angular) dependence of the strength of the radio waves from the antenna or other source.

In electromagnetics, an antenna's gain is a key performance parameter which combines the antenna's directivity and radiation efficiency. The term power gain has been deprecated by IEEE. In a transmitting antenna, the gain describes how well the antenna converts input power into radio waves headed in a specified direction. In a receiving antenna, the gain describes how well the antenna converts radio waves arriving from a specified direction into electrical power. When no direction is specified, gain is understood to refer to the peak value of the gain, the gain in the direction of the antenna's main lobe. A plot of the gain as a function of direction is called the antenna pattern or radiation pattern. It is not to be confused with directivity, which does not take an antenna's radiation efficiency into account.

A parabolic antenna is an antenna that uses a parabolic reflector, a curved surface with the cross-sectional shape of a parabola, to direct the radio waves. The most common form is shaped like a dish and is popularly called a dish antenna or parabolic dish. The main advantage of a parabolic antenna is that it has high directivity. It functions similarly to a searchlight or flashlight reflector to direct radio waves in a narrow beam, or receive radio waves from one particular direction only. Parabolic antennas have some of the highest gains, meaning that they can produce the narrowest beamwidths, of any antenna type. In order to achieve narrow beamwidths, the parabolic reflector must be much larger than the wavelength of the radio waves used, so parabolic antennas are used in the high frequency part of the radio spectrum, at UHF and microwave (SHF) frequencies, at which the wavelengths are small enough that conveniently sized reflectors can be used.

<span class="mw-page-title-main">Near and far field</span> Regions of an electromagnetic field

The near field and far field are regions of the electromagnetic (EM) field around an object, such as a transmitting antenna, or the result of radiation scattering off an object. Non-radiative near-field behaviors dominate close to the antenna or scatterer, while electromagnetic radiation far-field behaviors predominate at greater distances.

Radiation resistance is that part of an antenna's feedpoint electrical resistance caused by the emission of radio waves from the antenna. A radio transmitter excites with a radio frequency alternating current an antenna, which radiates the exciting energy as radio waves. Because the antenna is absorbing the energy it is radiating from the transmitter, the antenna's input terminals present a resistance to the current from the transmitter.

A helical antenna is an antenna consisting of one or more conducting wires wound in the form of a helix. A helical antenna made of one helical wire, the most common type, is called monofilar, while antennas with two or four wires in a helix are called bifilar, or quadrifilar, respectively.

In radio and telecommunications a dipole antenna or doublet is one of the two simplest and most widely-used types of antenna; the other is the monopole. The dipole is any one of a class of antennas producing a radiation pattern approximating that of an elementary electric dipole with a radiating structure supporting a line current so energized that the current has only one node at each far end. A dipole antenna commonly consists of two identical conductive elements such as metal wires or rods. The driving current from the transmitter is applied, or for receiving antennas the output signal to the receiver is taken, between the two halves of the antenna. Each side of the feedline to the transmitter or receiver is connected to one of the conductors. This contrasts with a monopole antenna, which consists of a single rod or conductor with one side of the feedline connected to it, and the other side connected to some type of ground. A common example of a dipole is the "rabbit ears" television antenna found on broadcast television sets. All dipoles are electrically equivalent to two monopoles mounted end-to-end and fed with opposite phases, with the ground plane between them made "virtual" by the opposing monopole.

In electromagnetics and antenna theory, the aperture of an antenna is defined as "A surface, near or on an antenna, on which it is convenient to make assumptions regarding the field values for the purpose of computing fields at external points. The aperture is often taken as that portion of a plane surface near the antenna, perpendicular to the direction of maximum radiation, through which the major part of the radiation passes."

A ‘T’-antenna, ‘T’-aerial, or flat-top antenna is a monopole radio antenna consisting of one or more horizontal wires suspended between two supporting radio masts or buildings and insulated from them at the ends. A vertical wire is connected to the center of the horizontal wires and hangs down close to the ground, connected to the transmitter or receiver. The shape of the antenna resembles the letter "T", hence the name. The transmitter power is applied, or the receiver is connected, between the bottom of the vertical wire and a ground connection.

<span class="mw-page-title-main">Isotropic radiator</span>

An isotropic radiator is a theoretical point source of waves which radiates the same intensity of radiation in all directions. It may be based on sound waves or electromagnetic waves, in which case it is also known as an isotropic antenna. It has no preferred direction of radiation, i.e., it radiates uniformly in all directions over a sphere centred on the source.

In electromagnetics, the antenna factor is defined as the ratio of the electric field E to the voltage V induced across the terminals of an antenna:

Antenna measurement techniques refers to the testing of antennas to ensure that the antenna meets specifications or simply to characterize it. Typical parameters of antennas are gain, bandwidth, radiation pattern, beamwidth, polarization, and impedance.

In electromagnetics, directivity is a parameter of an antenna or optical system which measures the degree to which the radiation emitted is concentrated in a single direction. It is the ratio of the radiation intensity in a given direction from the antenna to the radiation intensity averaged over all directions. Therefore, the directivity of a hypothetical isotropic radiator is 1, or 0 dBi.

<span class="mw-page-title-main">Clutter (radar)</span> Unwanted echoes

Clutter is the unwanted return (echoes) in electronic systems, particularly in reference to radars. Such echoes are typically returned from ground, sea, rain, animals/insects, chaff and atmospheric turbulences, and can cause serious performance issues with radar systems. What one person considers to be unwanted clutter, another may consider to be a wanted target. However, targets usually refer to point scatterers and clutter to extended scatterers. The clutter may fill a volume or be confined to a surface. A knowledge of the volume or surface area illuminated is required to estimated the echo per unit volume, η, or echo per unit surface area, σ°.

The two-rays ground-reflection model is a multipath radio propagation model which predicts the path losses between a transmitting antenna and a receiving antenna when they are in line of sight (LOS). Generally, the two antenna each have different height. The received signal having two components, the LOS component and the reflection component formed predominantly by a single ground reflected wave.

The ten-rays model is a mathematical model applied to the transmissions of radio signal in an urban area,

The six-rays model is applied in an urban or indoor environment where a radio signal transmitted will encounter some objects that produce reflected, refracted or scattered copies of the transmitted signal. These are called multipath signal components, they are attenuated, delayed and shifted from the original signal (LOS) due to a finite number of reflectors with known location and dielectric properties, LOS and multipath signal are summed at the receiver.

In the domain of wireless communication, air-to-ground channels (A2G) are used for linking airborne devices, such as drones and aircraft, with terrestrial communication equipment. These channels are instrumental in a wide array of applications, extending beyond commercial telecommunications — including important roles in 5G and forthcoming 6G networks, where aerial base stations are integral to Non-Terrestrial Networks — to encompass critical uses in emergency response, environmental monitoring, military communications, and the expanding domain of the internet of things (IoT). A comprehensive understanding of A2G channels, their operational mechanics, and distinct attributes is essential for the enhancement of wireless network performance.

References

1 2 3 4 5 6 Johnson, Richard (1984). Antenna Engineering Handbook (2nd ed.). New York, NY: McGraw-Hill, Inc. p. 1-12. ISBN 0-07-032291-0.
1 2 3 4 5 6 7 8 9 10 11 12 Friis, H.T. (May 1946). "A Note on a Simple Transmission Formula". IRE Proc. 34 (5): 254–256. doi:10.1109/JRPROC.1946.234568. S2CID 51630329.
↑ Stutzman, Warren; Thiele, Gary (1981). Antenna Theory and Design . John Wiley & Sons, Inc. p. 60. ISBN 0-471-04458-X.
1 2 3 Bevelacqua, Pete. "Friis Equation - (aka Friis Transmission Formula)". www.antenna-theory.com. Retrieved 2018-08-21.
↑ Jayakody, Dushantha Nalin K.; Thompson, John; Chatzinotas, Symeon; Durrani, Salman (2017-07-20). Wireless Information and Power Transfer: A New Paradigm for Green Communications. Springer. p. 193. ISBN 9783319566696.
↑ Shaw, Joseph A. (2013). "Radiometry and the Friis transmission equation". American Journal of Physics. 81 (1): 33–37. Bibcode:2013AmJPh..81...33S. doi:10.1119/1.4755780.
↑ Frid, H.; Holter, H.; Jonsson, B. L. G. (2015). "An Approximate Method for Calculating the Near-Field Mutual Coupling Between Line-of-Sight Antennas on Vehicles". IEEE Transactions on Antennas and Propagation. 63 (9): 4132–4138. Bibcode:2015ITAP...63.4132F. doi:10.1109/TAP.2015.2447003. S2CID 13059054.

External links

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[AEH-1] 1 2 3 4 5 6 Johnson, Richard (1984). Antenna Engineering Handbook (2nd ed.). New York, NY: McGraw-Hill, Inc. p. 1-12. ISBN 0-07-032291-0.

[Friis-2] 1 2 3 4 5 6 7 8 9 10 11 12 Friis, H.T. (May 1946). "A Note on a Simple Transmission Formula". IRE Proc. 34 (5): 254–256. doi:10.1109/JRPROC.1946.234568. S2CID 51630329.

[Stutz-3] Stutzman, Warren; Thiele, Gary (1981). Antenna Theory and Design . John Wiley & Sons, Inc. p. 60. ISBN 0-471-04458-X.

[:0-4] 1 2 3 Bevelacqua, Pete. "Friis Equation - (aka Friis Transmission Formula)". www.antenna-theory.com. Retrieved 2018-08-21.

[5] Jayakody, Dushantha Nalin K.; Thompson, John; Chatzinotas, Symeon; Durrani, Salman (2017-07-20). Wireless Information and Power Transfer: A New Paradigm for Green Communications. Springer. p. 193. ISBN 9783319566696.

[6] Shaw, Joseph A. (2013). "Radiometry and the Friis transmission equation". American Journal of Physics. 81 (1): 33–37. Bibcode:2013AmJPh..81...33S. doi:10.1119/1.4755780.

[7] Frid, H.; Holter, H.; Jonsson, B. L. G. (2015). "An Approximate Method for Calculating the Near-Field Mutual Coupling Between Line-of-Sight Antennas on Vehicles". IEEE Transactions on Antennas and Propagation. 63 (9): 4132–4138. Bibcode:2015ITAP...63.4132F. doi:10.1109/TAP.2015.2447003. S2CID 13059054.

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v t e Radio frequency propagation models
Free space	Free-space path loss Friis transmission equation Dipole field strength in free space
Terrain	ITU terrain model Egli model Longley–Rice Irregular Terrain Model (ITM) Two-ray ground-reflection model
Foliage	Weissberger's model Early ITU model One woodland terminal model Single vegetative obstruction model
Urban	Okumura model Hata model COST Hata model Young model Six-rays model Ten-rays model
Indoor	ITU model for indoor attenuation Log-distance path loss model
Other	VOACAP (HF) Area-to-area Lee model (900 MHz) Point-to-point Lee model (900 MHz) Longley–Rice model (20 MHz - 20 GHz)