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{{short description|One millionth of a second}} | {{short description|One millionth of a second}} | ||
{{refimprove|date=July 2009}} | |||
] | |||
{{Infobox unit | |||
| name = microsecond | |||
| image = | |||
| caption = | |||
| symbol = μs | |||
| standard = ] | |||
| quantity = ] | |||
| units1 = ] | |||
| inunits1 = {{val|e=-6|ul=s}} | |||
}} | |||
A '''microsecond''' is a unit of ] in the ] (SI) equal to one ] (0.000001 or 10<sup>−6</sup> or {{frac|1|1,000,000}}) of a ]. Its symbol is '''μs''', sometimes simplified to '''us''' when ] is not available. | A '''microsecond''' is a unit of ] in the ] (SI) equal to one ] (0.000001 or 10<sup>−6</sup> or {{frac|1|1,000,000}}) of a ]. Its symbol is '''μs''', sometimes simplified to '''us''' when ] is not available. | ||
A microsecond is to one second, as one second is to approximately 11.57 days. | |||
A microsecond is equal to 1000 ]s or {{frac|1|1,000}} of a ]. Because the next ] is 1000 times larger, measurements of 10<sup>−5</sup> and 10<sup>−4</sup> seconds are typically expressed as tens or hundreds of microseconds. | A microsecond is equal to 1000 ]s or {{frac|1|1,000}} of a ]. Because the next ] is 1000 times larger, measurements of 10<sup>−5</sup> and 10<sup>−4</sup> seconds are typically expressed as tens or hundreds of microseconds. | ||
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* 1 microsecond (1 ]s) – cycle time for ] {{val|1|e=6|ul=hertz}} (1 MHz), the inverse unit. This corresponds to radio wavelength ] ] (AM ] band), as can be calculated by multiplying 1 μs by the ] (approximately {{val|3.00|e=8|u=m/s}}). | * 1 microsecond (1 ]s) – cycle time for ] {{val|1|e=6|ul=hertz}} (1 MHz), the inverse unit. This corresponds to radio wavelength ] ] (AM ] band), as can be calculated by multiplying 1 μs by the ] (approximately {{val|3.00|e=8|u=m/s}}). | ||
* 1 microsecond – the length of time of a high-speed, commercial ] flash (see ]). | * 1 microsecond – the length of time of a high-speed, commercial ] flash (see ]). | ||
* 1 microsecond – ] takes place on the order of microseconds. | * 1 microsecond – ] takes place on the order of microseconds (thus this is the speed of ]). | ||
* 1.8 microseconds – the amount of time subtracted from the Earth's ] as a result of the ].<ref>{{cite news |last1=Gross |first1=R.S. |title=Japan quake may have shortened Earth days, moved axis |url=http://www.jpl.nasa.gov/news/news.php?release=2011-080 |access-date=23 August 2019 |agency=Jet Propulsion Laboratory |publisher=JPL News |date=14 March 2014}}</ref> | * 1.8 microseconds – the amount of time subtracted from the Earth's ] as a result of the ].<ref>{{cite news |last1=Gross |first1=R.S. |title=Japan quake may have shortened Earth days, moved axis |url=http://www.jpl.nasa.gov/news/news.php?release=2011-080 |access-date=23 August 2019 |agency=Jet Propulsion Laboratory |publisher=JPL News |date=14 March 2014}}</ref> | ||
* 2 microseconds – the lifetime of a ] particle | * 2 microseconds – the lifetime of a ] particle. | ||
* 2.68 microseconds – the amount of time subtracted from the Earth's day as a result of the ].<ref name="IndianOceanNASA">{{cite web | url=https://www.nasa.gov/home/hqnews/2005/jan/HQ_05011_earthquake.html | title=NASA Details Earthquake Effects on the Earth | publisher=NASA | date=January 10, 2005 | access-date=September 18, 2021 | last1=Cook-Anderson | first1=Gretchen | last2=Beasley | first2=Dolores}}</ref> | * 2.68 microseconds – the amount of time subtracted from the Earth's day as a result of the ].<ref name="IndianOceanNASA">{{cite web | url=https://www.nasa.gov/home/hqnews/2005/jan/HQ_05011_earthquake.html | title=NASA Details Earthquake Effects on the Earth | publisher=NASA | date=January 10, 2005 | access-date=September 18, 2021 | last1=Cook-Anderson | first1=Gretchen | last2=Beasley | first2=Dolores}}</ref> | ||
* 3.33564095 microseconds – the time taken by ] to travel one ] in a ] | * 3.33564095 microseconds – the time taken by ] to travel one ] in a ]. | ||
* 5.4 microseconds – the time taken by light to travel one ] in a vacuum (or radio waves point-to-point in a near vacuum) | * 5.4 microseconds – the time taken by light to travel one ] in a vacuum (or radio waves point-to-point in a near vacuum). | ||
* 8 |
* 8 microseconds – the time taken by light to travel one mile in typical ]. | ||
* 10 microseconds (μs) – cycle time for frequency ], radio wavelength ] ] | * 10 microseconds (μs) – cycle time for frequency ], radio wavelength ] ]. | ||
* 18 microseconds – net amount per year that the length of the day lengthens, largely due to ].<ref>{{Cite news|url=http://www.sciencealert.com/astronomers-find-a-day-on-earth-is-getting-longer-each-century|title=Earth's Days Are Getting 2 Milliseconds Longer Every 100 Years|last=MacDonald|first=Fiona|work=ScienceAlert|access-date=2017-03-08|language=en-gb}}</ref> | * 18 microseconds – net amount per year that the length of the day lengthens, largely due to ].<ref>{{Cite news|url=http://www.sciencealert.com/astronomers-find-a-day-on-earth-is-getting-longer-each-century|title=Earth's Days Are Getting 2 Milliseconds Longer Every 100 Years|last=MacDonald|first=Fiona|work=ScienceAlert|access-date=2017-03-08|language=en-gb}}</ref> | ||
* 20.8 microseconds – ] interval for digital audio with 48,000 samples/s | * 20.8 microseconds – ] interval for digital audio with 48,000 samples/s. | ||
* 22.7 microseconds – sampling interval for ] audio (44,100 samples/s) | * 22.7 microseconds – sampling interval for ] audio (44,100 samples/s). | ||
* 38 microseconds – discrepancy in ] ] time per day (compensated by clock speed) due to ]{{hsp}}<ref>{{cite web | url=http://www.astronomy.ohio-state.edu/~pogge/Ast162/Unit5/gps.html | title= GPS and Relativity | access-date=2011-10-01 | author= Richard Pogge }}</ref> | * 38 microseconds – discrepancy in ] ] time per day (compensated by clock speed) due to ]{{hsp}}.<ref>{{cite web | url=http://www.astronomy.ohio-state.edu/~pogge/Ast162/Unit5/gps.html | title= GPS and Relativity | access-date=2011-10-01 | author= Richard Pogge }}</ref> | ||
* 50 microseconds – cycle time for highest ] tone (20 kHz) | * 50 microseconds – cycle time for highest ] tone (20 kHz). | ||
* 50 microseconds – to read the access latency for a modern solid state drive which holds non-volatile computer data<ref></ref> | * 50 microseconds – to read the access latency for a modern solid state drive which holds non-volatile computer data.<ref></ref> | ||
* 100 microseconds (0.1 ms) – cycle time for frequency 10 kHz | * 100 microseconds (0.1 ms) – cycle time for frequency 10 kHz. | ||
* 125 microseconds – common sampling interval for telephone audio (8000 samples/s)<ref>{{Citation |last=Kumar |first=Anurag |title=Application Models and Performance Issues |date=2008 |url=https://linkinghub.elsevier.com/retrieve/pii/B9780123742544500041 |work=Wireless Networking |pages=53–79 |publisher=Elsevier |language=en |doi=10.1016/b978-012374254-4.50004-1 |isbn=978-0-12-374254-4 |access-date=2022-08-08 |last2=Manjunath |first2=D. |last3=Kuri |first3=Joy}}</ref> | * 125 microseconds – common sampling interval for telephone audio (8000 samples/s).<ref>{{Citation |last=Kumar |first=Anurag |title=Application Models and Performance Issues |date=2008 |url=https://linkinghub.elsevier.com/retrieve/pii/B9780123742544500041 |work=Wireless Networking |pages=53–79 |publisher=Elsevier |language=en |doi=10.1016/b978-012374254-4.50004-1 |isbn=978-0-12-374254-4 |access-date=2022-08-08 |last2=Manjunath |first2=D. |last3=Kuri |first3=Joy}}</ref> | ||
* 164 microseconds – ] of ]-214 | * 164 microseconds – ] of ]-214. | ||
* 240 microseconds – half-life of ]-277 | * 240 microseconds – half-life of ]-277. | ||
* 260 to 480 microseconds - return trip ICMP ping time, including operating system kernel TCP/IP processing and answer time, between two |
* 260 to 480 microseconds - return trip ICMP ping time, including operating system kernel TCP/IP processing and answer time, between two Gigabit Ethernet devices connected to the same local area network switch fabric. | ||
* 277.8 microseconds – a fourth (a 60th of a 60th of a second), used in astronomical calculations by ] and ] in 1000 and 1267 AD, respectively.<ref>{{cite book | * 277.8 microseconds – a fourth (a 60th of a 60th of a second), used in astronomical calculations by ] and ] in 1000 and 1267 AD, respectively.<ref>{{cite book | ||
|author=al-Biruni | |author=al-Biruni | ||
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|no-pp=true | |no-pp=true | ||
}}</ref> | }}</ref> | ||
* |
* 490 microseconds – time for light at a 1550 nm frequency to travel 100 km in a singlemode fiber optic cable (where speed of light is approximately 200 million metres per second due to its ]). | ||
* The average human eye ] takes 350,000 microseconds (just over {{frac|1|3}} second). | * The average human eye ] takes 350,000 microseconds (just over {{frac|1|3}} second). | ||
* The average human finger ] takes 150,000 microseconds (just over {{frac| |
* The average human finger ] takes 150,000 microseconds (just over {{frac|1|7}} second). | ||
* A ] illuminates for 1,000 microseconds. | * A ] illuminates for 1,000 microseconds. | ||
* Standard camera ] opens the shutter for 4,000 microseconds or 4 milliseconds. | * Standard camera ] opens the shutter for 4,000 microseconds or 4 milliseconds. | ||
* 584542 years |
* 584542 years of microseconds fit in 64 bits: (2**64)/(1e6*60*60*24*365.25). | ||
==See also== | ==See also== |
Latest revision as of 18:02, 18 November 2024
One millionth of a secondmicrosecond | |
---|---|
Unit system | SI |
Unit of | time |
Symbol | μs |
Conversions | |
1 μs in ... | ... is equal to ... |
SI units | 10 s |
A microsecond is a unit of time in the International System of Units (SI) equal to one millionth (0.000001 or 10 or 1⁄1,000,000) of a second. Its symbol is μs, sometimes simplified to us when Unicode is not available.
A microsecond is to one second, as one second is to approximately 11.57 days.
A microsecond is equal to 1000 nanoseconds or 1⁄1,000 of a millisecond. Because the next SI prefix is 1000 times larger, measurements of 10 and 10 seconds are typically expressed as tens or hundreds of microseconds.
Examples
- 1 microsecond (1 μs) – cycle time for frequency 1×10 hertz (1 MHz), the inverse unit. This corresponds to radio wavelength 300 m (AM medium wave band), as can be calculated by multiplying 1 μs by the speed of light (approximately 3.00×10 m/s).
- 1 microsecond – the length of time of a high-speed, commercial strobe light flash (see air-gap flash).
- 1 microsecond – protein folding takes place on the order of microseconds (thus this is the speed of carbon-based life).
- 1.8 microseconds – the amount of time subtracted from the Earth's day as a result of the 2011 Japanese earthquake.
- 2 microseconds – the lifetime of a muonium particle.
- 2.68 microseconds – the amount of time subtracted from the Earth's day as a result of the 2004 Indian Ocean earthquake.
- 3.33564095 microseconds – the time taken by light to travel one kilometre in a vacuum.
- 5.4 microseconds – the time taken by light to travel one mile in a vacuum (or radio waves point-to-point in a near vacuum).
- 8 microseconds – the time taken by light to travel one mile in typical single-mode fiber optic cable.
- 10 microseconds (μs) – cycle time for frequency 100 kHz, radio wavelength 3 km.
- 18 microseconds – net amount per year that the length of the day lengthens, largely due to tidal acceleration.
- 20.8 microseconds – sampling interval for digital audio with 48,000 samples/s.
- 22.7 microseconds – sampling interval for CD audio (44,100 samples/s).
- 38 microseconds – discrepancy in GPS satellite time per day (compensated by clock speed) due to relativity .
- 50 microseconds – cycle time for highest human-audible tone (20 kHz).
- 50 microseconds – to read the access latency for a modern solid state drive which holds non-volatile computer data.
- 100 microseconds (0.1 ms) – cycle time for frequency 10 kHz.
- 125 microseconds – common sampling interval for telephone audio (8000 samples/s).
- 164 microseconds – half-life of polonium-214.
- 240 microseconds – half-life of copernicium-277.
- 260 to 480 microseconds - return trip ICMP ping time, including operating system kernel TCP/IP processing and answer time, between two Gigabit Ethernet devices connected to the same local area network switch fabric.
- 277.8 microseconds – a fourth (a 60th of a 60th of a second), used in astronomical calculations by al-Biruni and Roger Bacon in 1000 and 1267 AD, respectively.
- 490 microseconds – time for light at a 1550 nm frequency to travel 100 km in a singlemode fiber optic cable (where speed of light is approximately 200 million metres per second due to its index of refraction).
- The average human eye blink takes 350,000 microseconds (just over 1⁄3 second).
- The average human finger snap takes 150,000 microseconds (just over 1⁄7 second).
- A camera flash illuminates for 1,000 microseconds.
- Standard camera shutter speed opens the shutter for 4,000 microseconds or 4 milliseconds.
- 584542 years of microseconds fit in 64 bits: (2**64)/(1e6*60*60*24*365.25).
See also
References
- Gross, R.S. (14 March 2014). "Japan quake may have shortened Earth days, moved axis". JPL News. Jet Propulsion Laboratory. Retrieved 23 August 2019.
- Cook-Anderson, Gretchen; Beasley, Dolores (January 10, 2005). "NASA Details Earthquake Effects on the Earth". NASA. Retrieved September 18, 2021.
- MacDonald, Fiona. "Earth's Days Are Getting 2 Milliseconds Longer Every 100 Years". ScienceAlert. Retrieved 2017-03-08.
- Richard Pogge. "GPS and Relativity". Retrieved 2011-10-01.
- Intel Solid State Drive Product Specification
- Kumar, Anurag; Manjunath, D.; Kuri, Joy (2008), "Application Models and Performance Issues", Wireless Networking, Elsevier, pp. 53–79, doi:10.1016/b978-012374254-4.50004-1, ISBN 978-0-12-374254-4, retrieved 2022-08-08
- al-Biruni (1879). The chronology of ancient nations: an English version of the Arabic text of the Athâr-ul-Bâkiya of Albîrûnî, or "Vestiges of the Past". Translated by Sachau C Edward. W. H. Allen. pp. 147–149. OCLC 9986841.
- R Bacon (2000) . The Opus Majus of Roger Bacon. translator: BR Belle. University of Pennsylvania Press. table facing page 231. ISBN 978-1-85506-856-8.
External links
Orders of magnitude of time | |
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by powers of ten | |
Negative powers | |
Positive powers |