 Radiation Resistance
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Radiation Resistance

Radiation resistance is that part of an antenna's feedpoint electrical resistance that is caused by the radiation of electromagnetic waves from the antenna. In radio transmission, a radio transmitter is connected to an antenna. The transmitter generates a radio frequency alternating current which is applied to the antenna, and the antenna radiates the energy in the alternating current 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. Unlike other resistances found in electrical circuits, radiation resistance is not due to the opposition (resistivity) of the material of the antenna conductors to electric current; it is a virtual resistance due to the antenna's loss of energy as radio waves. The radiation resistance $R_{\text{R}}$ can be defined as the value of resistance that would dissipate the same amount of power as radiated as radio waves by the antenna with the antenna input current passing through it. From Joule's law, it is equal to the total power $P_{\text{R}}$ radiated as radio waves by the antenna divided by the square of the rms current $I_{\text{rms}}$ into the antenna terminals: $R_{\text{R}}=P_{\text{R}}/I_{\text{rms}}^{2}$ .

The radiation resistance is determined by the geometry of the antenna and the operating frequency. The total feedpoint resistance at the antenna's terminals is equal to the radiation resistance plus the loss resistance due to ohmic losses in the antenna. In a receiving antenna the radiation resistance represents the source resistance of the antenna, and the portion of the received radio power consumed by the radiation resistance represents radio waves reradiated (scattered) by the antenna.

## Cause

Electromagnetic waves are radiated by electric charges when they are accelerated. In a transmitting antenna radio waves are generated by time varying electric currents, consisting of electrons accelerating as they flow back and forth in the metal antenna, driven by the electric field due to the oscillating voltage applied to the antenna by the radio transmitter. An electromagnetic wave carries momentum away from the electron which emitted it. The cause of radiation resistance is the radiation reaction, the recoil force on the electron when it emits a radio wave photon, which reduces its momentum. This is called the Abraham-Lorentz force. The recoil force is in a direction opposite to the electric field in the antenna accelerating the electron, reducing the average velocity of the electrons for a given driving voltage, so it acts as a resistance opposing the current.

## Radiation resistance and loss resistance

The radiation resistance is only part of the feedpoint resistance at the antenna terminals. An antenna has other energy losses which appear as additional resistance at the antenna terminals; ohmic resistance of the metal antenna elements, ground losses from currents induced in the ground, and dielectric losses in insulating materials. The total feedpoint resistance $R_{\text{IN}}$ is equal to the sum of the radiation resistance $R_{\text{R}}$ and loss resistance $R_{\text{L}}$ $R_{\text{IN}}=R_{\text{R}}+R_{\text{L}}$ The power $P_{\text{IN}}$ fed to the antenna is split proportionally between these two resistances.

$P_{\text{IN}}=I_{\text{IN}}^{2}(R_{\text{R}}+R_{\text{L}})$ $P_{\text{IN}}=P_{\text{R}}+P_{\text{L}}$ where

$P_{\text{R}}=I_{\text{IN}}^{2}R_{\text{R}}\quad$ and $\quad P_{\text{L}}=I_{\text{IN}}^{2}R_{\text{L}}$ The power $P_{\text{R}}$ consumed by radiation resistance is converted to radio waves, the desired function of the antenna, while the power $P_{\text{L}}$ consumed by loss resistance is converted to heat, representing a waste of transmitter power. So for minimum power loss it is desirable that the radiation resistance be much greater than the loss resistance. The ratio of the radiation resistance to the total feedpoint resistance is equal to the efficiency $\eta$ of the antenna.

$\eta ={P_{\text{R}} \over P_{\text{IN}}}={R_{\text{R}} \over R_{\text{R}}+R_{\text{L}}}$ To transfer maximum power to the antenna, the transmitter and feedline must be impedance matched to the antenna. This means the feedline must present to the antenna a resistance equal to the input resistance $R_{\text{IN}}$ and a reactance (capacitance or inductance) equal to the opposite of the antenna's reactance. If these impedances are not matched, the antenna will reflect some of the power back toward the transmitter, so not all the power will be radiated. The antenna's radiation resistance is usually the main part of its input resistance, so it determines what impedance matching is necessary and what types of transmission line would be well matched to the antenna.

## Effect of the feedpoint

In a resonant antenna, the current and voltage form standing waves along the length of the antenna element, so the magnitude of the current in the antenna varies sinusoidally along its length. The feedpoint, the place where the feed line from the transmitter is attached, can be located at different points along the antenna element. Since radiation resistance depends on the input current, it varies with the feedpoint. It is lowest for feedpoints located at a point of maximum current (an antinode), and highest for feedpoints located at a point of minimum current, a node, such as at the end of the element (theoretically, in an infinitesimally thin antenna element, radiation resistance is infinite at a node, but the finite thickness of actual antenna elements gives it a high but finite value, on the order of thousands of ohms). The choice of feedpoint is sometimes used as a convenient way to impedance match an antenna to its feed line, by attaching the feedline to the antenna at a point at which its input resistance is equal to the characteristic impedance of the feed line.

In order to give a meaningful value for the antenna efficiency, the radiation resistance and loss resistance must be referred to the same point on the antenna, usually the input terminals. Radiation resistance is usually calculated with respect to the maximum current $I_{\text{0}}$ in the antenna. If the antenna is fed at a point of maximum current, as in the common center-fed half-wave dipole or base-fed quarter-wave monopole, that value $R_{\text{R0}}$ is the radiation resistance. However if the antenna is fed at another point, the equivalent radiation resistance at that point $R_{\text{R1}}$ can easily be calculated from the ratio of antenna currents

$P_{\text{R}}=I_{\text{0}}^{2}R_{\text{R0}}=I_{\text{1}}^{2}R_{\text{R1}}$ $R_{\text{R1}}={\Big (}{I_{\text{0}} \over I_{\text{1}}}{\Big )}^{2}R_{\text{R0}}$ ## Receiving antennas

In a receiving antenna, the radiation resistance represents the source resistance of the antenna as a (Thevenin equivalent) source of power. Due to electromagnetic reciprocity, an antenna has the same radiation resistance when receiving radio waves as when transmitting. If the antenna is connected to an electrical load such as a radio receiver, the power received from radio waves striking the antenna is divided proportionally between the radiation resistance and loss resistance of the antenna and the load resistance. The power dissipated in the radiation resistance is due to radio waves reradiated (scattered) by the antenna. Maximum power is delivered to the receiver when it is impedance matched to the antenna. If the antenna is lossless, half the power absorbed by the antenna is delivered to the receiver, the other half is reradiated.

## Radiation resistance of common antennas

Antenna Radiation resistance
ohms
Source
Center-fed half-wave dipole 73.1 Kraus 1988:227
Balanis 2005:216
Short dipole of length $\lambda /50 $20\pi ^{2}{\Big (}{L \over \lambda }{\Big )}^{2}$ Kraus 1988:216
Balanis 2005:165,215
Base-fed quarter-wave monopole
over perfectly conducting ground
36.5 Balanis 2005:217
Stutzman & Thiele 2012:80
Short monopole of length $L\ll \lambda /4$ over perfectly conducting ground
$40\pi ^{2}{\Big (}{L \over \lambda }{\Big )}^{2}$ Stutzman & Thiele 2012:78-80
Resonant loop antenna, 1 $\lambda$ circumference ~100 Weston 2017:15
Schmitt 2002:236
Small loop of area $A$ with $N$ turns
(circumference $\ll \lambda /3$ )
$320\pi ^{4}{\Big (}{NA \over \lambda ^{2}}{\Big )}^{2}$ Kraus 1988:251
Balanis 2005:238
Small loop of area $A$ with $N$ turns
on a ferrite core of effective relative permeability $\mu _{\text{eff}}$ $320\pi ^{4}{\Big (}{\mu _{\text{eff}}NA \over \lambda ^{2}}{\Big )}^{2}$ Kraus 1988:259
Milligan 2005:260

The above figures assume the antenna is made of thin conductors and that the dipole antennas are sufficiently far away from the ground or grounded structures.

The half-wave dipole's radiation resistance of 73 ohms is near enough to the characteristic impedance of common 50 and 75 ohm coaxial cable that it can usually be fed directly without need of an impedance matching network. This is one reason for the wide use of the half wave dipole as a driven element in antennas.

### Relationship of monopoles and dipoles

The radiation resistance of a monopole antenna created by replacing one side of a dipole antenna by a perpendicular ground plane is one-half of the resistance of the original dipole antenna. This is because the monopole radiates only into half the space, the space above the plane, so the radiation pattern is identical to half of the dipole pattern and therefore with the same input current it radiates only half the power. This is not obvious from the formulas in the table because the derived monopole antenna is only half the length of the original dipole antenna. This can be shown by calculating the radiation resistance of a short monopole of half the length of a dipole

$R_{\text{R}}=40\pi ^{2}{\Big (}{L/2 \over \lambda }{\Big )}^{2}=10\pi ^{2}{\Big (}{L \over \lambda }{\Big )}^{2}\qquad$ (monopole of length L/2)

Comparing this to the formula for the short dipole shows the monopole has half the radiation resistance

$R_{\text{R}}=20\pi ^{2}{\Big (}{L \over \lambda }{\Big )}^{2}\qquad \qquad \qquad$ (dipole of length L)

## Calculation

Calculating the radiation resistance of an antenna directly from the reaction force on the electrons is very complicated, and presents conceptual difficulties in accounting for the self-force of the electron. Radiation resistance is instead calculated by computing the far-field radiation pattern of the antenna, the power flux (Poynting vector) at each angle, for a given antenna current. This is integrated over a sphere enclosing the antenna to give the total power $P_{\text{R}}$ radiated by the antenna. Then the radiation resistance is calculated from the power by conservation of energy, as the resistance the antenna must present to the input current to absorb the radiated power from the transmitter, using Joule's law $R_{\text{R}}=P_{\text{R}}/I_{\text{rms}}^{2}$ ## Small antennas

Electrically short antennas, antennas with a length much less than a wavelength, make poor transmitting antennas, as they cannot be fed efficiently due to their low radiation resistance. As can be seen in the above table, for antennas shorter than their fundamental resonant length ($\lambda /2$ for a dipole antenna, $\lambda /4$ for a monopole, circumference of $\lambda$ for a loop) the radiation resistance decreases with the square of their length. As the length is decreased the loss resistance, which is in series with the radiation resistance, makes up a larger fraction of the feedpoint resistance, so it consumes a larger fraction of the transmitter power, causing the efficiency of the antenna to decrease.

For example, navies use radio waves of about 15 - 30 kHz in the very low frequency (VLF) band to communicate with submerged submarines. A 15 kHz radio wave has a wavelength of 20 km. The powerful naval shore VLF transmitters which transmit to submarines use large monopole mast antennas which are limited by construction costs to heights of about 300 metres (980 ft). Although these are tall antennas by ordinary standards, at 15 kHz this is still only about .015 wavelength high, so VLF antennas are electrically short. From the table a .015$\lambda$ monopole antenna has a radiation resistance of about 0.09 ohm. It is extremely difficult to reduce the loss resistances of the antenna to this level. Since the ohmic resistance of the huge ground system and loading coil cannot be made lower than about 0.5 ohm, the efficiency of a simple vertical antenna is below 20%, so more than 80% of the transmitter power is lost in the ground resistance. To increase the radiation resistance, VLF transmitters use huge capacitively top-loaded antennas such as umbrella antennas and flattop antennas, in which an aerial network of horizontal wires is attached to the top of the vertical radiator to make a 'capacitor plate' to ground, to increase the current in the vertical radiator. However this can only increase the efficiency to 50 - 70% at most.

Small receiving antennas, such as the ferrite loopstick antennas used in AM radios, also have low radiation resistance and thus produce very low output. However at frequencies below about 30 MHz this is not such a problem, since the weak signal from the antenna can simply be amplified in the receiver.

At frequencies below 1 MHz the size of ordinary electrical circuits is so much smaller than the wavelength, that when considered as antennas they radiate an insignificant fraction of the power in them as radio waves. This explains why electrical circuits can be used with alternating current without losing energy as radio waves.

## Definition of variables

Symbol Unit Definition
$\lambda$ meter Wavelength of radio waves
$\pi$ none Constant = 3.14159
$\mu _{\text{eff}}$ none Effective relative permeability of ferrite rod in antenna
$A$ meter2 Cross sectional area of loop antenna
$f$ hertz Frequency of radio waves
$I_{\text{IN}}$ ampere RMS current into antenna terminals
$I_{\text{0}}$ ampere Maximum RMS current in antenna element
$I_{\text{1}}$ ampere RMS current at an arbitrary point in antenna element
$L$ meter Length of antenna
$N$ none Number of wire turns in loop antenna
$P_{\text{IN}}$ watt Electric power delivered to antenna terminals
$P_{\text{R}}$ watt Power radiated as radio waves by antenna
$P_{\text{L}}$ watt Power consumed in loss resistances of antenna
$R_{\text{R}}$ ohm Radiation resistance of antenna
$R_{\text{L}}$ ohm Equivalent loss resistance of antenna at input terminals
$R_{\text{IN}}$ ohm Input resistance of antenna
$R_{\text{R0}}$ ohm Radiation resistance at point of maximum current in antenna
$R_{\text{R1}}$ ohm Radiation resistance at arbitrary point in antenna

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