Radio noise
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In radio reception, radio noise (commonly referred to as radio static) is unwanted random radio frequency electrical signals, fluctuating voltages, always present in a radio receiver in addition to the desired radio signal.
Radio noise is a combination of natural electromagnetic atmospheric noise ("spherics", static) created by electrical processes in the atmosphere like lightning; from human-made radio frequency interference (RFI) from other electrical devices picked up by the receiver's antenna; and from thermal noise present in the receiver input circuits, mostly caused by the random thermal motion of molecules inside resistors.
Effects of noise on radio
[edit]Radio noise near in frequency to a received radio signal (in the receiver's passband) interferes (RFI) with the operation of the receiver's circuitry. The limiting noise source in a receiver depends on the frequency range in use: At frequencies below about 40 MHz but above about 20 MHz, nearby radio frequency interference caused by human-made devices is the main issue, and lightning in occasional storms that pass within line-of-sight of the antenna. Atmospheric noise is comparable to human-caused noise below 20 MHz, and particularly severe in the mediumwave and longwave bands, or even lower frequencies; below about 500 kHz atmospheric noise typically dominates.
The level of noise determines the maximum sensitivity and reception range of a radio receiver; if no noise were picked up with radio signals, even weak transmissions could be received at virtually any distance by making a radio receiver that had high enough amplification, with low enough internal-noise.
With radio noise present, if a radio source is so weak and far away that the radio signal in the receiver has a lower amplitude than the average noise, the noise will drown out the signal. The level of noise in a communications circuit is measured by the signal-to-noise ratio (SNR, S / N ), the ratio of the average amplitude of the signal voltage to the average amplitude of the noise voltage. When this ratio is below one (0 dB) the noise is greater than the signal, requiring special processing to recover the information, if that is even possible.
Atmospheric noise
[edit]Atmospheric noise ("spherics", static, or QRN) created by natural electrical events in the atmosphere, principally lightning in tropical storms. At frequencies below about 20 MHz the ionosphere traps radio waves inside the atmosphere – the same phenomenon that enables continent-wide up to world-wide communication in the shortwaves. Above about 30 MHz any noise freely radiates through the ionosphere and dissipates into space; at those higher frequencies naturally-caused noise only troubles radio receivers within line-of-sight of a nearby lightning storm. The same effect applies to human-caused radio interference.
Human caused radio interference
[edit]Human-caused radio frequency interference (RFI, EMI, or QRM) arises from electrical switches, motors, vehicle ignition circuits, computers, and other man-made sources tend to be above the thermal noise floor in the receiver's circuits. These noises are often also referred to as "static".
Human-caused electromagnetic interference (EMI) can disrupt the operation of any electronic equipment in general, not just radios, causing malfunction. In recent years standards have been developed for the levels of electromagnetic radiation that electronic equipment is permitted to radiate, and normal levels which equipment is expected to tolerate. These standards are aimed at ensuring what is referred to as electromagnetic compatibility (EMC).
Thermal noise
[edit]At very high frequency and ultra high frequency and above, these sources are often lower, and thermal noise is usually the limiting factor. In the most sensitive receivers at these frequencies, radio telescopes and satellite communication antennas, thermal noise is reduced by cooling the RF front end of the receiver to cryogenic temperatures. cosmic background noise is experienced at frequencies above about 15 MHz when highly directional antennas are pointed toward the sun or to certain other radio-bright regions of the sky, such as the center of the Milky Way Galaxy, or the planet Jupiter.
See also
[edit]References
[edit]- ^ Characteristics and Applications of Atmospheric Radio Noise Data (Report). International Radio Consultative Committee (CCIR). Geneva, CH: International Telecommunication Union (ITU). 1968. CCIR Report 322-3.; first CCIR Report 322 was 1963; revised first ed.; second is ISBN 92-61-01741-X.
Further reading
[edit]- Radio noise (Report). ITU-R Recommendation. Vol. P.372. Geneva, CH: International Telecommunication Union.
- Blackard, K.L.; Rappaport, T.S.; Bostian, C.W.; et al. (30 September 1993). "Measurements and models of radio frequency impulsive noise for indoor wireless communications". IEEE Journal on Selected Areas in Communications. 11 (7): 991–1001. doi:10.1109/49.233212. ISSN 0733-8716.
- Dalke, R.; Achatz, R.; Lo, Y.; Papazian, P.; Hufford, G. (6 August 2002) [11–13 August 1997]. Measurement and analysis of man-made noise in VHF and UHF bands. 1997 Wireless Communications Conference. IEEE Xplore. Boulder, CO: IEEE (published 1997). doi:10.1109/WCC.1997.622284. ISBN 0-7803-4194-5.
- Lauber, W.R.; Bertrand, J.M. (August 1999). "Statistics of motor vehicle ignition noise at VHF / UHF". IEEE Transactions on Electromagnetic Compatibility. 41 (3): 257–259. doi:10.1109/15.784164. ISSN 0018-9375.
- Sanchez, M.G.; de Haro, L.; Ramon, M.C.; Mansilla, A.; Ortega, C.M.; Oliver, D. (31 May 1999). "Impulsive noise measurements and characterization in a UHF digital TV channel". IEEE Transactions on Electromagnetic Compatibility. 41 (2): 124–136. doi:10.1109/15.765101. ISSN 0018-9375.
- Blankenship, T.K.; Rappaport, T.S. (28 February 1998). "Characteristics of impulsive noise in the 450 MHz band in hospitals and clinics". IEEE Transactions on Antennas and Propagation. 46 (2): 194–203. doi:10.1109/8.660963. ISSN 0018-926X.