The Info List - Metres

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The METRE (international spelling ) or METER (American spelling ) (from the Greek noun μέτρον, "measure") is the base unit of length in the International System of Units (SI). The SI unit symbol is M. The metre is defined as the length of the path travelled by light in a vacuum in 1/299 792 458 seconds .

The metre was originally defined in 1793 as one ten-millionth of the distance from the equator to the North Pole . In 1799, it was redefined in terms of a prototype metre bar (the actual bar used was changed in 1889). In 1960, the metre was redefined in terms of a certain number of wavelengths of a certain emission line of krypton-86 . In 1983, the current definition was adopted.

The imperial inch is defined as 0.0254 metres (2.54 centimetres or 25.4 millimetres). One metre is about  3 3⁄8 inches longer than a yard , i.e. about  39 3⁄8 inches.


* 1 Spelling * 2 Etymology

* 3 History of definition

* 3.1 Meridional definition * 3.2 International prototype metre bar * 3.3 Wavelength definition * 3.4 Speed of light definition * 3.5 Timeline

* 4 SI prefixed forms of metre * 5 Equivalents in other units * 6 See also * 7 Notes * 8 References * 9 Further reading


_Metre_ is the standard spelling of the metric unit for length in nearly all English-speaking nations except the United States and the Philippines, which use _meter_.

Measuring devices (such as ammeter , speedometer ) are spelled "-meter" in all variants of English. The suffix "-meter" has the same Greek origin as the unit of length.


The etymological roots of _metre_ can be traced to the Greek verb _μετρέω_ (metreo) (to measure, count or compare) and noun _μέτρον_ (metron) (a measure), which were used for physical measurement, for poetic metre and by extension for moderation or avoiding extremism (as in "be measured in your response"). This range of uses is also found in Latin (_metior_, _mensura_), French (_mètre_, _mesure_), English and other languages. The motto _ΜΕΤΡΩ ΧΡΩ_ (metro chro) in the seal of the International Bureau of Weights and Measures (BIPM), which was a saying of the Greek statesman and philosopher Pittacus of Mytilene and may be translated as "Use measure!", thus calls for both measurement and moderation.


Main article: History of the metre

In 1668 the English cleric and philosopher John Wilkins proposed in an essay a decimal-based unit of length, the _universal measure_ or _standard_ based on a pendulum with a one-second period . Christiaan Huygens had observed that length to be 38 Rijnland inches or 39.26 English inches . This is the equivalent of what is now known to be 997 mm. No official action was taken regarding this suggestion.

In 1670 Gabriel Mouton , Bishop of Lyon, also suggested a universal length standard with decimal multiples and divisions, to be based on a one-minute angle of the Earth's meridian arc or (as the Earth's circumference was not easy to measure) on a pendulum with a one-second period. In 1675, the Italian scientist Tito Livio Burattini , in his work _Misura Universale_, used the phrase _metro cattolico_ ("universal measure"), derived from the Greek μέτρον καθολικόν (_métron katholikón_), to denote the standard unit of length derived from a pendulum. As a result of the French Revolution , the French Academy of Sciences charged a commission with determining a single scale for all measures. On 7 October 1790 that commission advised the adoption of a decimal system, and on 19 March 1791 advised the adoption of the term _mètre_ ("measure"), a basic unit of length, which they defined as equal to one ten-millionth of the distance between the North Pole and the Equator , In 1793, the French National Convention adopted the proposal; this use of _metre_ in English began at least as early as 1797. Belfry, Dunkirk —the northern end of the meridian arc Fortress of Montjuïc —the southerly end of the meridian arc Creating the metre-alloy in 1874 at the Conservatoire des Arts et Métiers. Present Henri Tresca, George Matthey, Saint-Claire Deville and Debray


In 1791, the French Academy of Sciences selected the meridional definition over the pendular definition because the force of gravity varies slightly over the surface of the Earth, which affects the period of a pendulum.

To establish a universally accepted foundation for the definition of the metre, more accurate measurements of this meridian were needed. The French Academy of Sciences commissioned an expedition led by Jean Baptiste Joseph Delambre and Pierre Méchain , lasting from 1792 to 1799, which attempted to accurately measure the distance between a belfry in Dunkerque and Montjuïc castle in Barcelona to estimate the length of the meridian arc through Dunkerque. This portion of the meridian, assumed to be the same length as the Paris meridian , was to serve as the basis for the length of the half meridian connecting the North Pole with the Equator. The problem with this approach is that the exact shape of the Earth is not a simple mathematical shape, such as a sphere or oblate spheroid , at the level of precision required for defining a standard of length. The irregular and particular shape of the Earth smoothed to sea level is represented by a mathematical model called a geoid , which literally means "Earth-shaped". Despite these issues, in 1793 France adopted this definition of the metre as its official unit of length based on provisional results from this expedition. However, it was later determined that the first prototype metre bar was short by about 200 micrometres because of miscalculation of the flattening of the Earth, making the prototype about 0.02% shorter than the original proposed definition of the metre. Regardless, this length became the French standard and was progressively adopted by other countries in Europe.


In 1867 at the second general conference of the International Association of Geodesy held in Berlin, the question of an international standard unit of length was discussed in order to combine the measurements made in different countries to determine the size and shape of the Earth. The conference recommended the adoption of the metre and the creation of an international metre commission, according to the proposal of Johann Jacob Baeyer , Adolphe Hirsch and Carlos Ibáñez e Ibáñez de Ibero .

In the 1870s and in light of modern precision, a series of international conferences was held to devise new metric standards. The Metre Convention (_Convention du Mètre_) of 1875 mandated the establishment of a permanent International Bureau of Weights and Measures (BIPM: _Bureau International des Poids et Mesures_) to be located in Sèvres , France. This new organisation was to construct and preserve a prototype metre bar, distribute national metric prototypes, and maintain comparisons between them and non-metric measurement standards. The organisation created such a bar in 1889 at the first General Conference on Weights and Measures (CGPM: _Conférence Générale des Poids et Mesures_), establishing the _ International Prototype Metre _ as the distance between two lines on a standard bar composed of an alloy of 90% platinum and 10% iridium , measured at the melting point of ice.

The original international prototype of the metre is still kept at the BIPM under the conditions specified in 1889.


In 1893, the standard metre was first measured with an interferometer by Albert A. Michelson , the inventor of the device and an advocate of using some particular wavelength of light as a standard of length. By 1925, interferometry was in regular use at the BIPM. However, the International Prototype Metre remained the standard until 1960, when the eleventh CGPM defined the metre in the new International System of Units (SI) as equal to 1 650 763.73 wavelengths of the orange -red emission line in the electromagnetic spectrum of the krypton -86 atom in a vacuum .


To further reduce uncertainty, the 17th CGPM in 1983 replaced the definition of the metre with its current definition, thus fixing the length of the metre in terms of the second and the speed of light : The metre is the length of the path travelled by light in vacuum during a time interval of 1/7008299792458000000♠299792458 of a second.

This definition fixed the speed of light in vacuum at exactly 7008299792458000000♠299792458 metres per second (≈7008300000000000000♠300000 km/s). An intended by-product of the 17th CGPM's definition was that it enabled scientists to compare lasers accurately using frequency, resulting in wavelengths with one-fifth the uncertainty involved in the direct comparison of wavelengths, because interferometer errors were eliminated. To further facilitate reproducibility from lab to lab, the 17th CGPM also made the iodine-stabilised helium–neon laser "a recommended radiation" for realising the metre. For the purpose of delineating the metre, the BIPM currently considers the HeNe laser wavelength, λHeNe, to be 6993632991212580000♠632.99121258 nm with an estimated relative standard uncertainty (_U_) of 6989210000000000000♠2.1×10−11. This uncertainty is currently one limiting factor in laboratory realisations of the metre, and it is several orders of magnitude poorer than that of the second, based upon the caesium fountain atomic clock (_U_ = 6984500000000000000♠5×10−16). Consequently, a realisation of the metre is usually delineated (not defined) today in labs as 7006157980076204200♠1579800.762042(33) wavelengths of helium-neon laser light in a vacuum, the error stated being only that of frequency determination. This bracket notation expressing the error is explained in the article on measurement uncertainty .

Practical realisation of the metre is subject to uncertainties in characterising the medium, to various uncertainties of interferometry, and to uncertainties in measuring the frequency of the source. A commonly used medium is air, and the National Institute of Standards and Technology (NIST) has set up an online calculator to convert wavelengths in vacuum to wavelengths in air. As described by NIST, in air, the uncertainties in characterising the medium are dominated by errors in measuring temperature and pressure. Errors in the theoretical formulas used are secondary. By implementing a refractive index correction such as this, an approximate realisation of the metre can be implemented in air, for example, using the formulation of the metre as 7006157980076204200♠1579800.762042(33) wavelengths of helium–neon laser light in vacuum, and converting the wavelengths in a vacuum to wavelengths in air. Of course, air is only one possible medium to use in a realisation of the metre, and any partial vacuum can be used, or some inert atmosphere like helium gas, provided the appropriate corrections for refractive index are implemented.

The metre is _defined_ as the path length travelled by light in a given time and practical laboratory length measurements in metres are determined by counting the number of wavelengths of laser light of one of the standard types that fit into the length, and converting the selected unit of wavelength to metres. Three major factors limit the accuracy attainable with laser interferometers for a length measurement:

* uncertainty in vacuum wavelength of the source, * uncertainty in the refractive index of the medium, * least count resolution of the interferometer.

Of these, the last is peculiar to the interferometer itself. The conversion of a length in wavelengths to a length in metres is based upon the relation = c n f , {displaystyle lambda ={frac {c}{nf}},}

which converts the unit of wavelength λ to metres using _c_, the speed of light in vacuum in m/s. Here _n_ is the refractive index of the medium in which the measurement is made, and _f_ is the measured frequency of the source. Although conversion from wavelengths to metres introduces an additional error in the overall length due to measurement error in determining the refractive index and the frequency, the measurement of frequency is one of the most accurate measurements available.


_ Closeup of National Prototype Metre Bar No. 27, made in 1889 by the International Bureau of Weights and Measures (BIPM) and given to the United States, which served as the standard for defining all units of length in the US from 1893 to 1960

* 8 May 1790 – The French National Assembly decides that the length of the new metre would be equal to the length of a pendulum with a half-period of one second . * 30 March 1791 – The French National Assembly accepts the proposal by the French Academy of Sciences that the new definition for the metre be equal to one ten-millionth of the length of a quadrant along the Earth's meridian through Paris, that is the distance from the equator to the north pole. * 1795 – Provisional metre bar constructed of brass . Based on Bessel\'s ellipsoid and legally equal to 443.44 lines on the toise du Pérou_ (a standard French unit of length from 1747). * 10 December 1799 – The French National Assembly specifies the platinum metre bar, constructed on 23 June 1799 and deposited in the National Archives , as the final standard. Legally equal to 443.296 lines on the _toise du Pérou_. * 28 September 1889 – The 1st General Conference on Weights and Measures (CGPM) defines the metre as the distance between two lines on a standard bar of an alloy of platinum with 10% iridium , measured at the melting point of ice. * 6 October 1927 – The 7th CGPM redefines the metre as the distance, at 0 °C (273 K ), between the axes of the two central lines marked on the prototype bar of platinum-iridium, this bar being subject to one standard atmosphere of pressure and supported on two cylinders of at least 10 mm (1 cm) diameter, symmetrically placed in the same horizontal plane at a distance of 571 mm (57.1 cm) from each other. * 14 October 1960 – The 11th CGPM defines the metre as 7006165076373000000♠1650763.73 wavelengths in a vacuum of the radiation corresponding to the transition between the 2p10 and 5d5 quantum levels of the krypton -86 atom . * 21 October 1983 – The 17th CGPM defines the metre as the length of the path travelled by light in a vacuum during a time interval of 1/299 792 458 of a second . * 2002 – The International Committee for Weights and Measures (CIPM) considers the metre to be a unit of proper length and thus recommends this definition be restricted to "lengths ℓ which are sufficiently short for the effects predicted by general relativity to be negligible with respect to the uncertainties of realisation".

Definitions of the metre since 1795 BASIS OF DEFINITION DATE Absolute uncertainty Relative uncertainty

1/10 000 000 part of the quadrant along the meridian , measurement by Delambre and Méchain (443.296 lines) 1795 500–100 μm 6996100000000000000♠10−4

First prototype _Mètre des Archives _ platinum bar standard 1799 50–10 μm 6995100000000000000♠10−5

Platinum-iridium bar at melting point of ice (1st CGPM ) 1889 0.2–0.1 µm (200–100 nm) 6993100000000000000♠10−7

Platinum-iridium bar at melting point of ice, atmospheric pressure, supported by two rollers (7th CGPM) 1927 n.a. n.a.

Hyperfine atomic transition; 7006165076373000000♠1650763.73 wavelengths of light from a specified transition in krypton-86 (11th CGPM) 1960 4 nm 6991400000000000000♠4×10−9

Length of the path travelled by light in a vacuum in 1/299 792 458 of a second (17th CGPM) 1983 0.1 nm 6990100000000000000♠10−10


SI prefixes are often employed to denote decimal multiples and submultiples of the metre, as shown in the table below. As indicated in the table, some are commonly used, while others are not. Long distances are usually expressed in km, astronomical units (149.6 Gm), light-years (10 Pm), or parsecs (31 Pm), rather than in Mm, Gm, Tm, Pm, Em, Zm or Ym; "30 cm", "30 m", and "300 m" are more common than "3 dm", "3 dam", and "3 hm", respectively.

The terms _micron_ and (occasionally) _millimicron_ are often used instead of _micrometre_ (μm) and _nanometre_ (nm), but this practice is officially discouraged.

SI multiples for metre (m) SUBMULTIPLES



10−1 m dm decimetre 101 m dam decametre

10−2 m CM CENTIMETRE 102 m hm hectometre


10−6 m µM MICROMETRE 106 m Mm megametre

10−9 m NM NANOMETRE 109 m Gm gigametre

10−12 m pm picometre 1012 m Tm terametre

10−15 m fm femtometre 1015 m Pm petametre

10−18 m am attometre 1018 m Em exametre

10−21 m zm zeptometre 1021 m Zm zettametre

10−24 m ym yoctometre 1024 m Ym yottametre

Common prefixed units are in BOLD face.


Metric unit expressed in non- SI units Non-SI unit expressed in metric units

1 metre ≈ 1.0936 yard

1 yard ≡ 0.9144 metre

1 metre ≈ 39.370 inches

1 inch ≡ 0.0254 metre

1 centimetre ≈ 6999393700000000000♠0.39370 inch

1 inch ≡ 2.54 centimetres

1 millimetre ≈ 6998393700000000000♠0.039370 inch

1 inch ≡ 25.4 millimetres

1 metre ≡ 1×1010 ångström

1 ångström ≡ 1×10−10 metre

1 nanometre ≡ 10 ångström

1 ångström ≡ 100 picometres

Within this table, "inch" and "yard" mean "international inch" and "international yard" respectively, though approximate conversions in the left column hold for both international and survey units. "≈" means "is approximately equal to"; "≡" means "equal by definition" or "is exactly equal to".

One metre is exactly equivalent to 10 000/254 inches and to 10 000/9 144 yards.

A simple mnemonic aid exists to assist with conversion, as three "3"s: 1 metre is nearly equivalent to 3 feet  3 3⁄8 inches. This gives an overestimate of 0.125 mm. However, the practice of memorising such conversion formulas has been discouraged in favour of practice and visualisation of metric units.

The ancient Egyptian cubit was about 0.5 m (surviving rods are 523–529 mm). Scottish and English definitions of the ell (two cubits) were 941 mm (0.941 m) and 1 143 mm (1.143 m) respectively. The ancient Parisian _toise_ (fathom) was slightly shorter than 2 m and was standardised at exactly 2 m in the mesures usuelles system, such that 1 m was exactly  1⁄2 toise. The Russian versta was 1.0668 km. The Swedish mil was 10.688 km, but was changed to 10 km when Sweden converted to metric units.


* Conversion of units for comparisons with other units * International System of Units * Introduction to the metric system * ISO 1 – standard reference temperature for length measurements * Length measurement * Metre Convention * Metric system * Metric prefix * Metrication * Orders of magnitude (length) * SI prefix * Speed of light


* ^ "Base unit definitions: Meter". National Institute of Standards and Technology . Retrieved 28 September 2010. * ^ _A_ _B_ "17th General Conference on Weights and Measures (1983), Resolution 1.". Retrieved 19 September 2012. * ^ The most recent official brochure about the International System of Units (SI), written in French by the _Bureau international des poids et mesures_, International Bureau of Weights and Measures (BIPM) uses the spelling _metre_; an English translation, included to make the SI standard "more widely accessible" also uses the spelling _metre_ (BIPM, 2006 , p. 130_ff_). However, in 2008 the U.S. English translation published by the U.S. National Institute of Standards and Technology (NIST) chose to use the spelling _meter_ in accordance with the United States Government Printing Office Style Manual. The Metric Conversion Act of 1975 gives the Secretary of Commerce of the US the responsibility of interpreting or modifying the SI for use in the US. The Secretary of Commerce delegated this authority to the Director of the National Institute of Standards and Technology (Turner ). In 2008, NIST published the US version (Taylor and Thompson, 2008a ) of the English text of the eighth edition of the BIPM publication _Le Système international d'unités (SI)_ (BIPM, 2006). In the NIST publication, the spellings "meter", "liter" and "deka" are used rather than "metre", "litre" and "deca" as in the original BIPM English text (Taylor and Thompson (2008a), p. iii ). The Director of the NIST officially recognised this publication, together with Taylor and Thompson (2008b) , as the "legal interpretation" of the SI for the United States (Turner ). Thus, the spelling _metre_ is referred to as the "international spelling"; the spelling _meter_, as the "American spelling". * ^ Naughtin, Pat (2008). "Spelling metre or meter" (PDF). _ Metrication Matters_. Retrieved 12 March 2017. * ^ "Meter vs. metre". _Grammarist_. Retrieved 12 March 2017. * ^ The Philippines uses English as an official language and this largely follows American English since the country became a colony of the United States. While the law that converted the country to use the metric system uses _metre_ (Batas Pambansa Blg. 8 ) following the SI spelling, in actual practice, _meter_ is used in government and everyday commerce, as evidenced by laws (_kilometer_, Republic Act No. 7160 ), Supreme Court decisions (_meter_, G.R. No. 185240 ), and national standards (_centimeter_, PNS/BAFS 181:2016 ). * ^ _Cambridge Advanced Learner\'s Dictionary_. Cambridge University Press . 2008. Retrieved 19 September 2012. , s.v. ammeter, meter, parking meter, speedometer. * ^ _American Heritage Dictionary of the English Language_ (3rd ed.). Boston: Houghton Mifflin . 1992. , s.v. meter. * ^ "-meter - definition of -meter in English". Oxford Dictionaries. * ^ _A_ _B_ "Chapter 7: Measure" in _An Essay towards a Real Character and a Philosophical Language _ — John Wilkins F.R.S. 1668, pp. 191-192 * ^ George Sarton (1935). "The First Explanation of Decimal Fractions and Measures (1585). Together with a History of the Decimal Idea and a Facsimile (No. XVII) of Stevin's Disme". _Isis_. 23 (1): 153–244. JSTOR 225223 . doi :10.1086/346940 . * ^ ('decimalization is not of the essence of the metric system; the real significance of this is that it was the first great attempt to define terrestrial units of measure in terms of an unvarying astronomical or geodetic constant.) The metre was in fact defined as one ten-millionth of one-quarter of the earth's circumference at sea-level.' Joseph Needham , _ Science and Civilisation in China ,_ Cambridge University Press, 1962 vol.4, pt.1, p.42. * ^ Agnoli, Paolo (2004). _Il senso della misura: la codifica della realtà tra filosofia, scienza ed esistenza umana_ (in Italian). Armando Editore. pp. 93–94,101. Retrieved 13 October 2015. * ^ "Rapport sur le choix d\'une unité de mesure, lu à l\'Académie des sciences, le 19 mars 1791" (in French). Gallica.bnf.fr. 15 October 2007. Retrieved 25 March 2013. * ^ Paolo Agnoli and Giulio D’Agostini,\'Why does the meter beat the second?,\' December, 2004 pp.1–29. * ^ Oxford English Dictionary , Clarendon Press 2nd ed.1989, vol.IX p.697 col.3. * ^ _A_ _B_ Hirsch, Adolphe (1891). "Don Carlos IBANEZ (1825 - 1891)" (PDF). _Bureau International des Poids et Mesures_. p. 8. Retrieved 22 May 2017. * ^ "BIPM - International Metre Commission". _www.bipm.org_. Retrieved 26 May 2017. * ^ "A Note on the History of the IAG". _IAG Homepage_. Retrieved 26 May 2017. * ^ National Institute of Standards and Technology 2003; Historical context of the SI: Unit of length (meter) * ^ Marion, Jerry B. (1982). _Physics For Science and Engineering_. CBS College Publishing. p. 3. ISBN 4-8337-0098-0 . * ^ _A_ _B_ _C_ "Iodine (λ≈633 nm)" (PDF). _MEP (_Mise en Pratique_)_. BIPM. 2003. Retrieved 16 December 2011. * ^ The term "relative standard uncertainty" is explained by NIST on their web site: "Standard Uncertainty and Relative Standard Uncertainty". _The NIST Reference on constants, units, and uncertainties: Fundamental physical constants_. NIST. Retrieved 19 December 2011. * ^ National Research Council 2010 . * ^ National Institute of Standards and Technology 2011 . * ^ _A_ _B_ A more detailed listing of errors can be found in Beers, John S; Penzes, William B (December 1992). "§4 Re-evaluation of measurement errors" (PDF). _NIST length scale interferometer measurement assurance; NIST document NISTIR 4998_. pp. 9 _ff_. Retrieved 17 December 2011. * ^ The formulas used in the calculator and the documentation behind them are found at "Engineering metrology toolbox: Refractive index of air calculator". NIST. 23 September 2010. Retrieved 16 December 2011. The choice is offered to use either the modified Edlén equation or the Ciddor equation. The documentation provides a discussion of how to choose between the two possibilities. * ^ "§VI: Uncertainty and range of validity". _Engineering metrology toolbox: Refractive index of air calculator_. NIST. 23 September 2010. Retrieved 16 December 2011. * ^ Dunning, F. B.; Hulet, Randall G. (1997). "Physical limits on accuracy and resolution: setting the scale". _Atomic, molecular, and optical physics: electromagnetic radiation, Volume 29, Part 3_. Academic Press. p. 316. ISBN 0-12-475977-7 . The error can be reduced tenfold if the chamber is filled with an atmosphere of helium rather than air. * ^ "Recommended values of standard frequencies". BIPM. 9 September 2010. Retrieved 22 January 2012. * ^ National Physical Laboratory 2010 . * ^ The BIPM maintains a list of recommended radiations on their web site. * ^ _A_ _B_ Zagar, 1999, pp. 6–65_ff_ . * ^ Barbrow & Judson 1976, appendix 6. * ^ Taylor and Thompson (2008a), Appendix 1, p. 70. * ^ Taylor and Thompson (2008a), Appendix 1, p. 77. * ^ Cardarelli 2003 * ^ Definition of the metre Resolution 1 of the 17th meeting of the CGPM (1983) * ^ Taylor & Thompson 2003, p. 11. * ^ Astin ">


* 17th General Conference on Weights and Measures . (1983). Resolution 1. International Bureau of Weights and Measures . * Astin, A. V. ">(PDF). Derived from a prior work by Louis A. Fisher (1905). USA: US Department of Commerce , National Bureau of Standards . LCCN 76-600055 . NBS Special Publication 447; NIST SP 447; 003-003-01654-3. Retrieved 12 October 2015. * Beers, J.S. ">(PDF) (in French). Bureau International des Poids et Mesures. 2006. Retrieved 18 August 2008.

* HTML version. Retrieved 24 August 2008.

* Bureau International des Poids et Mesures. (n.d.). _Resolutions of the CGPM_ (search facility). Retrieved 3 June 2006. * Bureau International des Poids et Mesures. (n.d.). _The BIPM and the evolution of the definition of the metre_. Retrieved 3 June 2006. * Bureau of Agriculture and Fisheries Standards (Philippines). _Philippine National Standard for Abaca Fiber Grading and Classification - Decorticated (PNS/BAFS 181:2016)_. * Cardarelli, François (2003). "Chapter 2: The International system of Units" (PDF). _Encydopaedia of scientific units, weights, and measures: their SI equivalences and origins_. Springer-Verlag London Limited. Table 2.1, p. 5. ISBN 1-85233-682-X . Retrieved 26 January 2017. Data from Giacomo, P., Du platine à la lumière , _Bull. Bur. Nat. Metrologie_, 102 (1995) 5–14. * Humerfelt, Sigurd. (26 October 2010). _How WGS 84 defines Earth_. Retrieved 29 April 2011. * Layer, H.P. (2008). _Length—Evolution from Measurement Standard to a Fundamental Constant_. Gaithersburg, MD: National Institute of Standards and Technology. Retrieved 18 August 2008. * Mohr, P., Taylor, B.N., and David B. Newell, D. (28 December 2007). _CODATA Recommended Values of the Fundamental Physical Constants: 2006_. Gaithersburg, MD: National Institute of Standards and Technology. Retrieved 18 August 2008.

* National Institute of Standards and Technology. (December 2003). _The NIST Reference on Constants, Units, and Uncertainty: International System of Units (SI)_ (web site):

* _SI base units_. Retrieved 18 August 2008. * _Definitions of the SI base units_. Retrieved 18 August 2008. * _Historical context of the SI: Meter_. Retrieved 26 May 2010.

* National Institute of Standards and Technology. (27 June 2011). _NIST-F1 Cesium Fountain Atomic Clock_. Author. * National Physical Laboratory. (25 March 2010). _Iodine-Stabilised Lasers_. Author. * "Maintaining the SI unit of length". National Research Council Canada. 5 February 2010. Archived from the original on 4 December 2011. * Republic of the Philippines. (2 December 1978). _Batas Pambansa Blg. 8: An Act Defining the Metric System and its Units, Providing for its Implementation and for Other Purposes_. Author. * Republic of the Philippines. (10 October 1991). _Republic Act No. 7160: The Local Government Code of the Philippines_. Author. * Penzes, W. (29 December 2005). _Time Line for the Definition of the Meter_. Gaithersburg, MD: National Institute of Standards and Technology – Precision Engineering Division. Retrieved 4 December 2010. * Supreme Court of the Philippines ( Second Division). (20 January 2010). _G.R. No. 185240_. Author. * Taylor, B.N. and Thompson, A. (Eds.). (2008a). _The International System of Units (SI)_. United States version of the English text of the eighth edition (2006) of the International Bureau of Weights and Measures publication _Le Système International d’ Unités (SI)_ ( Special Publication 330). Gaithersburg, MD: National Institute of Standards and Technology. Retrieved 18 August 2008. * Taylor, B.N. and Thompson, A. (2008b). _Guide for the Use of the International System of Units_ ( Special Publication 811). Gaithersburg, MD: National Institute of Standards and Technology. Retrieved 23 August 2008. * Tibo Qorl. (2005) The History of the Meter (Translated by Sibille Rouzaud). Retrieved 18 August 2008. * Turner, J. (Deputy Director of the National Institute of Standards and Technology). (16 May 2008)."Interpretation of the International System of Units (the Metric System of Measurement) for the United States". _Federal Register_ Vol. 73, No. 96, p. 28432-3. * Wilkins, J. (c. 2007). An essay towards a real character, and a philosophical language. Metrication Matters. (Reprinted from title page and pp. 190–194 of original, 1668, London: Royal Society) * Zagar, B.G. (1999). Laser interferometer displacement sensors in J.G. Webster (ed.). _The Measurement, Instrumentation, and Sensors Handbook._ CRC Press. ISBN 0-8493-8347-1 .


_ Wikimedia Commons has media related to METRE _.

* Alder, Ken. (2002). _The Measure of All Things : The Seven-Year Odyssey and Hidden Error That Transformed the World._ Free Press, New York ISBN 0-7432-1675-X

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* Conversion of units * History of the metric system * Metric prefixes * Proposed redefinitions * Systems of measurement


* v * t * e

SI units of length

From smallest to largest (left to right). Commonly used units shown in BOLD ITALICS_.

* yoctometre (1×10−24 m) * zeptometre * attometre * femtometre * picometre * nanometre * micrometre * _MILLIMETRE _ * _CENTIMETRE _ * decimetre * _METRE (M)_ * decametre * hectometre * _KILOMETRE _ * megametre * gigametre * terametre * petametre * exametre * zettametre * yottametre (1×1024 m)

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