Noise figure: Difference between revisions
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'''Noise figure''' (NF) and '''noise factor''' (''F'') are measures of degradation of the [[signal-to-noise ratio]] (SNR), caused by components in a [[Signal chain (signal processing chain)|signal chain]]. It is a number by which the performance of an amplifier or a radio receiver can be specified, with lower values indicating better performance. |
'''Noise figure''' (NF) and '''noise factor''' (''F'') are measures of degradation of the [[signal-to-noise ratio]] (SNR), caused by components in a [[Signal chain (signal processing chain)|signal chain]]. It is a number by which the performance of an amplifier or a radio receiver can be specified, with lower values indicating better performance. |
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The noise factor is defined as the ratio of the |
The noise factor is defined as the ratio of the [[signal-to-noise ratio]] at the input to the [[signal-to-noise ratio]] at the output. The noise factor is thus the ratio of input SNR to output SNR. |
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The noise ''figure'' is simply the noise ''factor'' expressed in [[decibel]]s (dB).<ref>{{Cite web|url=http://www.satsig.net/noise.htm|title = Noise temperature, Noise Figure and Noise Factor}}</ref> |
The noise ''figure'' is simply the noise ''factor'' expressed in [[decibel]]s (dB).<ref>{{Cite web|url=http://www.satsig.net/noise.htm|title = Noise temperature, Noise Figure and Noise Factor}}</ref> |
Revision as of 02:51, 13 March 2022
Noise figure (NF) and noise factor (F) are measures of degradation of the signal-to-noise ratio (SNR), caused by components in a signal chain. It is a number by which the performance of an amplifier or a radio receiver can be specified, with lower values indicating better performance.
The noise factor is defined as the ratio of the signal-to-noise ratio at the input to the signal-to-noise ratio at the output. The noise factor is thus the ratio of input SNR to output SNR.
The noise figure is simply the noise factor expressed in decibels (dB).[1]
General
The noise figure is the difference in decibels (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 Boltzmann's 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]
where SNRi and SNRo are the input and output signal-to-noise ratios respectively. The SNR quantities are power ratios. The noise figure NF is defined as the noise factor in dB:
where SNRi, dB and SNRo, dB are in decibels (dB). These formulae are only valid when the input termination is at standard noise temperature T0 = 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 Te:[4]
Attenuators have a noise factor F equal to their attenuation ratio L when their physical temperature equals T0. More generally, for an attenuator at a physical temperature T, the noise temperature is Te = (L − 1)T, giving a noise factor
Noise factor of cascaded devices
If several devices are cascaded, the total noise factor can be found with Friis' formula:[5]
where Fn is the noise factor for the n-th device, and Gn 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 noise factor may be expressed as a function of the additional output referred noise power and the power gain of an amplifier.
Derivation
From the definition of noise factor[3]
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 , the amplified signal and the amplified input noise ,
Substituting the output SNR to the noise factor definition,[6]
In cascaded systems 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.
See also
- Noise
- Noise (electronic)
- Noise figure meter
- Noise level
- Thermal noise
- Signal-to-noise ratio
- Y-factor
References
- ^ "Noise temperature, Noise Figure and Noise Factor".
- ^ Agilent 2010, p. 7
- ^ a b Agilent 2010, p. 5 .
- ^ Agilent 2010, p. 7 with some rearrangement from Te = T0(F − 1).
- ^ Agilent 2010, p. 8 .
- ^ Aspen Core. Derivation of noise figure equations (DOCX), pp. 3–4
- Keysight, Fundamentals of RF and Microwave Noise Figure Measurements (PDF), Application Note, 57-1, Published September 01, 2019.
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).