Noise figure

Last updated April 06, 2024

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 or a radio receiver, with lower values indicating better performance.

The noise factor is defined as the ratio of the output noise power of a device to the portion thereof attributable to thermal noise in the input termination at standard noise temperature T₀ (usually 290 K). The noise factor is thus the ratio of actual output noise to that which would remain if the device itself did not introduce noise, which is equivalent to the ratio of input SNR to output SNR.

The noise factor and noise figure are related, with the former being a unitless ratio and the latter being the logarithm of the noise factor, expressed in units of decibels (dB).^[1]

General

The noise figure is the difference in decibel (dB) between the noise output of the actual receiver to the noise output of an "ideal" receiver with the same overall gain and bandwidth when the receivers are connected to matched sources at the standard noise temperature T₀ (usually 290 K). The noise power from a simple load is equal to kTB, where k is the Boltzmann constant, T is the absolute temperature of the load (for example a resistor), and B is the measurement bandwidth.

This makes the noise figure a useful figure of merit for terrestrial systems, where the antenna effective temperature is usually near the standard 290 K. In this case, one receiver with a noise figure, say 2 dB better than another, will have an output signal-to-noise ratio that is about 2 dB better than the other. However, in the case of satellite communications systems, where the receiver antenna is pointed out into cold space, the antenna effective temperature is often colder than 290 K.^[2] In these cases a 2 dB improvement in receiver noise figure will result in more than a 2 dB improvement in the output signal-to-noise ratio. For this reason, the related figure of effective noise temperature is therefore often used instead of the noise figure for characterizing satellite-communication receivers and low-noise amplifiers.

In heterodyne systems, output noise power includes spurious contributions from image-frequency transformation, but the portion attributable to thermal noise in the input termination at standard noise temperature includes only that which appears in the output via the principal frequency transformation of the system and excludes that which appears via the image frequency transformation.

Definition

The noise factor $F$ of a system is defined as^[3]

$F={\frac {\mathrm {SNR} _{\text{i}}}{\mathrm {SNR} _{\text{o}}}}$

where $SNR i$ and $SNR o$ are the input and output signal-to-noise ratios respectively. The $SNR$ quantities are unitless power ratios. Note that this specific definition is only valid for an input signal of which the noise is N_i=kT₀B.

The noise figure $NF$ is defined as the noise factor in units of decibels (dB):

$\mathrm {NF} =10\log _{10}(F)=10\log _{10}\left({\frac {\mathrm {SNR} _{\text{i}}}{\mathrm {SNR} _{\text{o}}}}\right)=\mathrm {SNR} _{\text{i, dB}}-\mathrm {SNR} _{\text{o, dB}}$

where $SNR i, dB$ and $SNR o, dB$ are in units of (dB). These formulae are only valid when the input termination is at standard noise temperature $T 0 = 290 K$ , although in practice small differences in temperature do not significantly affect the values.

The noise factor of a device is related to its noise temperature $T e$ :^[4]

F=1+{\frac {T_{\text{e}}}{T_{0}}}.

Attenuators have a noise factor $F$ equal to their attenuation ratio $L$ when their physical temperature equals $T 0$ . More generally, for an attenuator at a physical temperature $T$ , the noise temperature is $T e = (L - 1) T$ , giving a noise factor

F=1+{\frac {(L-1)T}{T_{0}}}.

Noise factor of cascaded devices

If several devices are cascaded, the total noise factor can be found with Friis' formula:^[5]

F=F_{1}+{\frac {F_{2}-1}{G_{1}}}+{\frac {F_{3}-1}{G_{1}G_{2}}}+{\frac {F_{4}-1}{G_{1}G_{2}G_{3}}}+\cdots +{\frac {F_{n}-1}{G_{1}G_{2}G_{3}\cdots G_{n-1}}},

where $F n$ is the noise factor for the $n$ -th device, and $G n$ is the power gain (linear, not in dB) of the $n$ -th device. The first amplifier in a chain usually has the most significant effect on the total noise figure because the noise figures of the following stages are reduced by stage gains. Consequently, the first amplifier usually has a low noise figure, and the noise figure requirements of subsequent stages is usually more relaxed.

Noise factor as a function of additional noise

The source outputs a signal of power
S
i
{\displaystyle S_{i}}
and noise of power
N
i
{\displaystyle N_{i}}
. Both signal and noise get amplified. However, in addition to the amplified noise from the source, the amplifier adds additional noise to its output denoted
N
a
{\displaystyle N_{a}}
. Therefore, the SNR at the amplifier's output is lower than at its input. NoiseFactorDefinition.svg — The source outputs a signal of power $S_{i}$ and noise of power $N_{i}$ . Both signal and noise get amplified. However, in addition to the amplified noise from the source, the amplifier adds additional noise to its output denoted $N_{a}$ . Therefore, the SNR at the amplifier's output is lower than at its input.

The noise factor may be expressed as a function of the additional output referred noise power $N_{a}$ and the power gain $G$ of an amplifier.

$F=1+{\frac {N_{a}}{N_{i}G}}$

Derivation

From the definition of noise factor^[3]

F={\frac {\mathrm {SNR} _{\text{i}}}{\mathrm {SNR} _{\text{o}}}}={\frac {\frac {S_{i}}{N_{i}}}{\frac {S_{o}}{N_{o}}}},

and assuming a system which has a noisy single stage amplifier. The signal to noise ratio of this amplifier would include its own output referred noise $N_{a}$ , the amplified signal $S_{i}G$ and the amplified input noise $N_{i}G$ ,

{\frac {S_{o}}{N_{o}}}={\frac {S_{i}G}{N_{a}+N_{i}G}}

Substituting the output SNR to the noise factor definition,^[6]

F={\frac {\frac {S_{i}}{N_{i}}}{\frac {S_{i}G}{N_{a}+N_{i}G}}}={\frac {N_{a}+N_{i}G}{N_{i}G}}=1+{\frac {N_{a}}{N_{i}G}}

In cascaded systems $N_{i}$ does not refer to the output noise of the previous component. An input termination at the standard noise temperature is still assumed for the individual component. This means that the additional noise power added by each component is independent of the other components.

Optical noise figure

The above describes noise in electrical systems. The optical noise figure is discussed in multiple sources.^[7]^[8]^[9]^[10]^[11] Electric sources generate noise with a power spectral density, or energy per mode, equal to $kT$ , where $k$ is the Boltzmann constant and $T$ is the absolute temperature. One mode has two quadratures, i.e. the amplitudes of $cos$ $\mathrm {\omega } t$ and $sin$ $\mathrm {\omega } t$ oscillations of voltages, currents or fields. However, there is also noise in optical systems. In these, the sources have no fundamental noise. Instead the energy quantization causes notable shot noise in the detector. In an optical receiver which can output one available mode or two available quadratures this corresponds to a noise power spectral density, or energy per mode, of $hf$ where $h$ is the Planck constant and $f$ is the optical frequency. In an optical receiver with only one available quadrature the shot noise has a power spectral density, or energy per mode, of only $hf /2$ .

In the 1990s, an optical noise figure has been defined.^[7] This has been called $F pnf$ for photon number fluctuations.^[8] The powers needed for SNR and noise factor calculation are the electrical powers caused by the current in a photodiode. SNR is the square of mean photocurrent divided by variance of photocurrent. Monochromatic or sufficiently attenuated light has a Poisson distribution of detected photons. If, during a detection interval the expectation value of detected photons is $n$ then the variance is also $n$ and one obtains $SNR pnf,in$ = $n 2 / n$ = $n$ . Behind an optical amplifier with power gain $G$ there will be a mean of $Gn$ detectable signal photons. In the limit of large $n$ the variance of photons is $Gn (2 n sp (G -1)+1)$ where $n sp$ is the spontaneous emission factor. One obtains $SNR pnf,out$ = $G 2 n 2 /(Gn (2 n sp (G -1)+1))$ = $n /(2 n sp (1-1/ G)+1/ G)$ . Resulting optical noise factor is $F pnf$ = $SNR pnf,in / SNR pnf,out$ = $2 n sp (1-1/ G)+1/ G$ .

$F pnf$ is in conceptual conflict^[9]^[10] with the electrical noise factor, which is now called $F e$ :

Photocurrent $I$ is proportional to optical power $P$ . $P$ is proportional to squares of a field amplitude (electric or magnetic). So, the receiver is nonlinear in amplitude. The "Power" needed for $SNR pnf$ calculation is proportional to the 4th power of the signal amplitude. But for $F e$ in the electrical domain the power is proportional to the square of the signal amplitude.

If $SNR pnf$ is a noise factor then its definition must be independent of measurement apparatus and frequency. Consider the signal "Power" in the sense of $SNR pnf$ definition. Behind an amplifier it is proportional to $G 2 n 2$ . We may replace the photodiode by a thermal power meter, and measured photocurrent $I$ by measured temperature change $\mathrm {\Delta \theta }$ . "Power", being proportional to $I 2$ or $P 2$ , is also proportional to $(\mathrm {\Delta \theta } )$ $2$ . Thermal power meters can be built at all frequencies. Hence it is possible to lower the frequency from optical (say 200 THz) to electrical (say 200 MHz). Still there, "Power" must be proportional to $(\mathrm {\Delta \theta } )$ $2$ or $P 2$ . Electrical power $P$ is proportional to the square $U 2$ of voltage $U$ . But "Power" is proportional to $U 4$ .

These implications are in obvious conflict with ~150 years of physics. They are compelling consequence of calling $F pnf$ a noise factor, or noise figure when expressed in dB.

At any given electrical frequency, noise occurs in both quadratures, i.e. in phase (I) and in quadrature (Q) with the signal. Both these quadratures are available behind the electrical amplifier. The same holds in an optical amplifier. But the direct detection photoreceiver needed for measurement of $SNR pnf$ takes mainly the in-phase noise into account whereas quadrature noise can be neglected for high $n$ . Also, the receiver outputs only one baseband signal, corresponding to quadrature. So, one quadrature or degree-of-freedom is lost.

For an optical amplifier with large $G$ it holds $F pnf$ ≥ 2 whereas for an electrical amplifier it holds $F e$ ≥ 1.

Moreover, today's long-haul optical fiber communication is dominated by coherent optical I&Q receivers but $F pnf$ does not describe the SNR degradation observed in these.

Another optical noise figure $F ase$ for amplified spontaneous emission has been defined.^[8] But the noise factor $F ase$ is not the SNR degradation factor in any optical receiver.

All the above conflicts are resolved by the optical in-phase and quadrature noise factor and figure $F o,IQ$ .^[9]^[10] It can be measured using a coherent optical I&Q receiver. In these, power of the output signal is proportional to the square of an optical field amplitude because they are linear in amplitude. They pass both quadratures. For an optical amplifier it holds $F o,IQ$ = $n sp (1-1/ G)+1/ G$ ≥ 1. Quantity $n sp (1-1/ G)$ is the input-referred number of added noise photons per mode.

$F o,IQ$ and $F pnf$ can easily be converted into each other. For large $G$ it holds $F o,IQ$ = $F pnf /2$ or, when expressed in dB, $F o,IQ$ is 3 dB less than $F pnf$ . The ideal $F o,IQ$ in dB equals 0 dB. This describes the known fact that the sensitivity of an ideal optical I&Q receiver is not improved by an ideal optical preamplifier.

Related Research Articles

<span class="mw-page-title-main">Bandwidth (signal processing)</span> Range of usable frequencies

Bandwidth is the difference between the upper and lower frequencies in a continuous band of frequencies. It is typically measured in unit of hertz.

The decibel is a relative unit of measurement equal to one tenth of a bel (B). It expresses the ratio of two values of a power or root-power quantity on a logarithmic scale. Two signals whose levels differ by one decibel have a power ratio of 10^1/10 or root-power ratio of 10^1⁄20.

Noise-equivalent power (NEP) is a measure of the sensitivity of a photodetector or detector system. It is defined as the signal power that gives a signal-to-noise ratio of one in a one hertz output bandwidth. An output bandwidth of one hertz is equivalent to half a second of integration time. The units of NEP are watts per square root hertz. The NEP is equal to the noise amplitude spectral density divided by the responsivity. The fundamental equation is $.$

In electronics, noise temperature is one way of expressing the level of available noise power introduced by a component or source. The power spectral density of the noise is expressed in terms of the temperature that would produce that level of Johnson–Nyquist noise, thus:

<span class="mw-page-title-main">Shot noise</span> Type of electronic noise

Shot noise or Poisson noise is a type of noise which can be modeled by a Poisson process.

Signal-to-noise ratio 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 noise power, often expressed in decibels. A ratio higher than 1:1 indicates more signal than noise.

In telecommunications, a third-order intercept point (IP₃ or TOI) is a specific figure of merit associated with the more general third-order intermodulation distortion (IMD3), which is a measure for weakly nonlinear systems and devices, for example receivers, linear amplifiers and mixers. It is based on the idea that the device nonlinearity can be modeled using a low-order polynomial, derived by means of Taylor series expansion. The third-order intercept point relates nonlinear products caused by the third-order nonlinear term to the linearly amplified signal, in contrast to the second-order intercept point that uses second-order terms.

The total harmonic distortion is a measurement of the harmonic distortion present in a signal and is defined as the ratio of the sum of the powers of all harmonic components to the power of the fundamental frequency. Distortion factor, a closely related term, is sometimes used as a synonym.

In information theory, the Shannon–Hartley theorem tells the maximum rate at which information can be transmitted over a communications channel of a specified bandwidth in the presence of noise. It is an application of the noisy-channel coding theorem to the archetypal case of a continuous-time analog communications channel subject to Gaussian noise. The theorem establishes Shannon's channel capacity for such a communication link, a bound on the maximum amount of error-free information per time unit that can be transmitted with a specified bandwidth in the presence of the noise interference, assuming that the signal power is bounded, and that the Gaussian noise process is characterized by a known power or power spectral density. The law is named after Claude Shannon and Ralph Hartley.

The sensitivity of an electronic device, such as a communications system receiver, or detection device, such as a PIN diode, is the minimum magnitude of input signal required to produce a specified output signal having a specified signal-to-noise ratio, or other specified criteria. In general, it is the signal level required for a particular quality of received information.

The asymptotic gain model is a representation of the gain of negative feedback amplifiers given by the asymptotic gain relation:

In signal processing, the output of the matched filter is given by correlating a known delayed signal, or template, with an unknown signal to detect the presence of the template in the unknown signal. This is equivalent to convolving the unknown signal with a conjugated time-reversed version of the template. The matched filter is the optimal linear filter for maximizing the signal-to-noise ratio (SNR) in the presence of additive stochastic noise.

Friis formula or Friis's formula, named after Danish-American electrical engineer Harald T. Friis, is either of two formulas used in telecommunications engineering to calculate the signal-to-noise ratio of a multistage amplifier. One relates to noise factor while the other relates to noise temperature.

This article illustrates some typical operational amplifier applications. A non-ideal operational amplifier's equivalent circuit has a finite input impedance, a non-zero output impedance, and a finite gain. A real op-amp has a number of non-ideal features as shown in the diagram, but here a simplified schematic notation is used, many details such as device selection and power supply connections are not shown. Operational amplifiers are optimised for use with negative feedback, and this article discusses only negative-feedback applications. When positive feedback is required, a comparator is usually more appropriate. See Comparator applications for further information.

In telecommunications, the carrier-to-noise ratio, often written CNR or C/N, is the signal-to-noise ratio (SNR) of a modulated signal. The term is used to distinguish the CNR of the radio frequency passband signal from the SNR of an analog base band message signal after demodulation. For example, with FM radio, the strength of the 100 MHz carrier with modulations would be considered for CNR, whereas the audio frequency analogue message signal would be for SNR; in each case, compared to the apparent noise. If this distinction is not necessary, the term SNR is often used instead of CNR, with the same definition.

In digital photography, the image sensor format is the shape and size of the image sensor.

Signal-to-noise ratio (SNR) is used in imaging to characterize image quality. The sensitivity of a imaging system is typically described in the terms of the signal level that yields a threshold level of SNR.

A minimum detectable signal is a signal at the input of a system whose power allows it to be detected over the background electronic noise of the detector system. It can alternately be defined as a signal that produces a signal-to-noise ratio of a given value m at the output. In practice, m is usually chosen to be greater than unity. In some literature, the name sensitivity is used for this concept.

In information theory and telecommunication engineering, the signal-to-interference-plus-noise ratio (SINR) is a quantity used to give theoretical upper bounds on channel capacity in wireless communication systems such as networks. Analogous to the signal-to-noise ratio (SNR) used often in wired communications systems, the SINR is defined as the power of a certain signal of interest divided by the sum of the interference power and the power of some background noise. If the power of noise term is zero, then the SINR reduces to the signal-to-interference ratio (SIR). Conversely, zero interference reduces the SINR to the SNR, which is used less often when developing mathematical models of wireless networks such as cellular networks.

An RF chain is a cascade of electronic components and sub-units which may include amplifiers, filters, mixers, attenuators and detectors. It can take many forms, for example, as a wide-band receiver-detector for electronic warfare (EW) applications, as a tunable narrow-band receiver for communications purposes, as a repeater in signal distribution systems, or as an amplifier and up-converters for a transmitter-driver. In this article, the term RF covers the frequency range "Medium Frequencies" up to "Microwave Frequencies", i.e. from 100 kHz to 20 GHz.

References

↑ "Noise temperature, Noise Figure and noise factor".
↑ Agilent 2010 , p. 7
1 2 Agilent 2010 , p. 5.
↑ Agilent 2010 , p. 7 with some rearrangement from $T e = T 0 (F - 1)$ .
↑ Agilent 2010 , p. 8.
↑ Aspen Core. Derivation of noise figure equations (DOCX), pp. 3–4
1 2 E. Desurvire, Erbium doped fiber amplifiers: Principles and Applications, Wiley, New York, 1994
1 2 3 H. A. Haus, "The noise figure of optical amplifiers," in IEEE Photonics Technology Letters, vol. 10, no. 11, pp. 1602-1604, Nov. 1998, doi: 10.1109/68.726763
1 2 3 R. Noe, "Consistent Optical and Electrical Noise Figure," in Journal of Lightwave Technology, 2022, doi: 10.1109/JLT.2022.3212936, https://ieeexplore.ieee.org/document/9915356
1 2 3 R. Noe, "Noise Figure and Homodyne Noise Figure" Photonic Networks; 24th ITG-Symposium, Leipzig, Germany, 09-10 May 2023, pp. 85-91, https://ieeexplore.ieee.org/abstract/document/10173081, presentation https://www.vde.com/resource/blob/2264664/dc0e3c85c8e0cb386cbfa215fe499c4c/noise-figure-and-homodyne-noise-figure-data.pdf
↑ H. A. Haus, "Noise Figure Definition Valid From RF to Optical Frequencies", in IEEE Journal of Selected Topics in Quantum Electronics, Vol. 6, NO. 2, March/April 2000, pp. 240–247

Keysight, Fundamentals of RF and Microwave Noise Figure Measurements (PDF), Application Note, 57-1, Published September 01, 2019., archived (PDF) from the original on 2022-10-09

External links

Noise Figure Calculator 2- to 30-Stage Cascade
Noise Figure and Y Factor Method Basics and Tutorial
Mobile phone noise figure

This article incorporates public domain material from Federal Standard 1037C. General Services Administration. Archived from the original on 2022-01-22. (in support of MIL-STD-188).

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.

[1] "Noise temperature, Noise Figure and noise factor".

[2] Agilent 2010 , p. 7

[:0-3] 1 2 Agilent 2010 , p. 5.

[4] Agilent 2010 , p. 7 with some rearrangement from $T e = T 0 (F - 1)$ .

[5] Agilent 2010 , p. 8.

[6] Aspen Core. Derivation of noise figure equations (DOCX), pp. 3–4

[Desurvire1994-7] 1 2 E. Desurvire, Erbium doped fiber amplifiers: Principles and Applications, Wiley, New York, 1994

[Haus1998-8] 1 2 3 H. A. Haus, "The noise figure of optical amplifiers," in IEEE Photonics Technology Letters, vol. 10, no. 11, pp. 1602-1604, Nov. 1998, doi: 10.1109/68.726763

[Noe2022-9] 1 2 3 R. Noe, "Consistent Optical and Electrical Noise Figure," in Journal of Lightwave Technology, 2022, doi: 10.1109/JLT.2022.3212936, https://ieeexplore.ieee.org/document/9915356

[NoeNF2023-10] 1 2 3 R. Noe, "Noise Figure and Homodyne Noise Figure" Photonic Networks; 24th ITG-Symposium, Leipzig, Germany, 09-10 May 2023, pp. 85-91, https://ieeexplore.ieee.org/abstract/document/10173081, presentation https://www.vde.com/resource/blob/2264664/dc0e3c85c8e0cb386cbfa215fe499c4c/noise-figure-and-homodyne-noise-figure-data.pdf

[Haus2000-11] H. A. Haus, "Noise Figure Definition Valid From RF to Optical Frequencies", in IEEE Journal of Selected Topics in Quantum Electronics, Vol. 6, NO. 2, March/April 2000, pp. 240–247

[1]

[2]

[3]

[4]

[5]

[6]

[7]

[8]

[9]

[10]

[11]