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Friis formula or Friis's formula (sometimes Friis' formula), named after Danish-American electrical engineer Harald T. Friis, is either of two formulas used in
telecommunications engineering Telecommunications Engineering is a subfield of electrical engineering which seeks to design and devise systems of communication at a distance. The work ranges from basic circuit design to strategic mass developments. A telecommunication enginee ...
to calculate the
signal-to-noise ratio Signal-to-noise ratio (SNR or S/N) is a measure used in science and engineering that compares the level of a desired signal to the level of background noise. SNR is defined as the ratio of signal power to the noise power, often expressed in deci ...
of a multistage
amplifier An amplifier, electronic amplifier or (informally) amp is an electronic device that can increase the magnitude of a signal (a time-varying voltage or current). It may increase the power significantly, or its main effect may be to boost the v ...
. One relates to
noise factor Noise figure (NF) and noise factor (''F'') are figures of merit that indicate degradation of the signal-to-noise ratio (SNR) that is caused by components in a signal chain. These figures of merit are used to evaluate the performance of an amplifie ...
while the other relates to
noise temperature In electronics, noise temperature is one way of expressing the level of available noise power introduced by a component or source. (This is to be distinguished from Temperature Noise in Thermodynamics or Principal Interferrometric Analysis Over C ...
.


The Friis formula for noise factor

Friis's formula is used to calculate the total
noise factor Noise figure (NF) and noise factor (''F'') are figures of merit that indicate degradation of the signal-to-noise ratio (SNR) that is caused by components in a signal chain. These figures of merit are used to evaluate the performance of an amplifie ...
of a cascade of stages, each with its own
noise factor Noise figure (NF) and noise factor (''F'') are figures of merit that indicate degradation of the signal-to-noise ratio (SNR) that is caused by components in a signal chain. These figures of merit are used to evaluate the performance of an amplifie ...
and
power gain The power gain of an electrical network is the ratio of an output power to an input power. Unlike other signal gains, such as voltage and current gain, "power gain" may be ambiguous as the meaning of terms "input power" and "output power" is not alw ...
(assuming that the impedances are matched at each stage). The total
noise factor Noise figure (NF) and noise factor (''F'') are figures of merit that indicate degradation of the signal-to-noise ratio (SNR) that is caused by components in a signal chain. These figures of merit are used to evaluate the performance of an amplifie ...
can then be used to calculate the total
noise figure Noise figure (NF) and noise factor (''F'') are figures of merit that indicate degradation of the signal-to-noise ratio (SNR) that is caused by components in a signal chain. These figures of merit are used to evaluate the performance of an amplifier ...
. The total
noise factor Noise figure (NF) and noise factor (''F'') are figures of merit that indicate degradation of the signal-to-noise ratio (SNR) that is caused by components in a signal chain. These figures of merit are used to evaluate the performance of an amplifie ...
is given as where F_i and G_i are the noise factor and available
power gain The power gain of an electrical network is the ratio of an output power to an input power. Unlike other signal gains, such as voltage and current gain, "power gain" may be ambiguous as the meaning of terms "input power" and "output power" is not alw ...
, respectively, of the ''i''-th stage, and ''n'' is the number of stages. Both magnitudes are expressed as ratios, not in decibels.


Consequences

An important consequence of this formula is that the overall noise figure of a
radio receiver In radio communications, a radio receiver, also known as a receiver, a wireless, or simply a radio, is an electronic device that receives radio waves and converts the information carried by them to a usable form. It is used with an antenna. Th ...
is primarily established by the noise figure of its first amplifying stage. Subsequent stages have a diminishing effect on
signal-to-noise ratio Signal-to-noise ratio (SNR or S/N) is a measure used in science and engineering that compares the level of a desired signal to the level of background noise. SNR is defined as the ratio of signal power to the noise power, often expressed in deci ...
. For this reason, the first stage amplifier in a receiver is often called the
low-noise amplifier A low-noise amplifier (LNA) is an electronic amplifier that amplifies a very low-power signal without significantly degrading its signal-to-noise ratio. An amplifier will increase the power of both the signal and the noise present at its input, ...
(LNA). The overall receiver noise "factor" is then :F_\mathrm = F_\mathrm + \frac where F_\mathrm is the overall noise factor of the subsequent stages. According to the equation, the overall noise factor, F_\mathrm, is dominated by the noise factor of the LNA, F_\mathrm, if the gain is sufficiently high. The resultant Noise Figure expressed in dB is: :\mathrm_\mathrm=10 \log(F_\mathrm)


Derivation

For a derivation of Friis' formula for the case of three cascaded amplifiers (n=3) consider the image below. A source outputs a signal of power S_i and noise of power N_i. Therefore the SNR at the input of the receiver chain is \text_i = S_i/N_i. The signal of power S_i gets amplified by all three amplifiers. Thus the signal power at the output of the third amplifier is S_o = S_i \cdot G_1 G_2 G_3. The noise power at the output of the amplifier chain consists of four parts: *The amplified noise of the source (N_i \cdot G_1 G_2 G_3) *The output referred noise of the first amplifier N_ amplified by the second and third amplifier (N_ \cdot G_2 G_3) *The output referred noise of the second amplifier N_ amplified by the third amplifier (N_ \cdot G_3) *The output referred noise of the third amplifier N_ Therefore the total noise power at the output of the amplifier chain equals :N_o = N_i G_1 G_2 G_3 + N_ G_2 G_3 + N_ G_3 + N_ and the SNR at the output of the amplifier chain equals :\text_o = \frac. The total noise factor may now be calculated as quotient of the input and output SNR: :F_\text = \frac = \frac = 1 + \frac + \frac + \frac Using the definitions of the noise factors of the amplifiers we get the final result: :F_\text = \underbrace_ + \underbrace_ + \underbrace_ = F_1 + \frac + \frac. General derivation for a cascade of n amplifiers: The total noise figure is given as the relation of the signal-to-noise ratio at the cascade input \mathrm=\frac to the signal-to-noise ratio at the cascade output \mathrm=\frac as F_=\frac=\frac\frac. The total input power of the k-th amplifier in the cascade (noise and signal) is S_+N_. It is amplified according to the amplifier's power gain G_k. Additionally, the amplifier adds noise with power N_. Thus the output power of the k-th amplifier is G_k \left( S_+N_ \right) + N_. For the entire cascade, one obtains the total output power S_\mathrm + N_\mathrm = \left( \left( \left( \left( S_+N_ \right) G_1 + N_ \right) G_2 + N_ \right) G_3 + N_ \right) G_4 + \dots The output signal power thus rewrites as S_\mathrm=S_\mathrm\prod_^ G_k whereas the output noise power can be written as N_\mathrm = N_\mathrm \prod_^G_k+\sum_^N_ \prod_^ + N_ Substituting these results into the total noise figure leads to F_\mathrm=\frac = 1 + \sum_^ \frac+ \frac = 1 + \sum_^ \frac+ \frac = 1 + \frac + \sum_^ \frac+ \frac Now, using F_k=1+\frac as the
noise figure Noise figure (NF) and noise factor (''F'') are figures of merit that indicate degradation of the signal-to-noise ratio (SNR) that is caused by components in a signal chain. These figures of merit are used to evaluate the performance of an amplifier ...
of the individual k -th amplifier, one obtains F_\mathrm = F_1 + \sum_^ \frac + \frac = F_1 + \frac + \frac + \frac + \dots + \frac


The Friis formula for noise temperature

Friis's formula can be equivalently expressed in terms of
noise temperature In electronics, noise temperature is one way of expressing the level of available noise power introduced by a component or source. (This is to be distinguished from Temperature Noise in Thermodynamics or Principal Interferrometric Analysis Over C ...
:


Published references

*J.D. Kraus, ''Radio Astronomy'', McGraw-Hill, 1966.


Online references

*RF Caf

Cascaded noise figure. *Microwave Encyclopedi

{{Webarchive, url=https://web.archive.org/web/20130517182715/http://www.microwaves101.com/encyclopedia/cascadeanalysis.cfm , date=2013-05-17 Cascade analysis. *Friis biography at IEE

Noise (electronics) Equations