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Metre

January 26, 2023

This article is about the unit of length. For other uses of "metre" or "meter", see Meter (disambiguation).

The metre (British spelling) or meter (American spelling; see spelling differences) (from the French unit mètre, from the Greek noun μέτρον, "measure"), symbol m, is the primary unit of length in the International System of Units (SI), though its prefixed forms are also used relatively frequently.

metre
Seal of the International Bureau of Weights and Measures (BIPM) – Use measure (Greek: ΜΕΤΡΩ ΧΡΩ)
General information
Unit systemSI
Unit oflength
Symbolm[1]
Conversions
1 m[1] in ...... is equal to ...
   SI units   
   Imperial/US units   
  • ≈ 1.0936 yd
  • ≈ 3.2808 ft
  • ≈ 39.37 in
   Nautical units   ≈ 0.00053996 nmi

The metre was originally defined in 1793 as one ten-millionth of the distance from the equator to the North Pole along a great circle, so the Earth's circumference is approximately 40000 km. In 1799, the metre 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. The current definition was adopted in 1983 and modified slightly in 2002 to clarify that the metre is a measure of proper length. From 1983 until 2019, the metre was formally defined as the length of the path travelled by light in a vacuum in 1/299792458 of a second. After the 2019 redefinition of the SI base units, this definition was rephrased to include the definition of a second in terms of the caesium frequency ΔνCs.

Spelling

Metre is the standard spelling of the metric unit for length in nearly all English-speaking nations except the United States[2][3][4][5] and the Philippines,[6] which use meter. Other West Germanic languages, such as German and Dutch, and North Germanic languages, such as Danish, Norwegian, and Swedish,[7] likewise spell the word Meter or meter.

Measuring devices (such as ammeter, speedometer) are spelled "-meter" in all variants of English.[8] The suffix "-meter" has the same Greek origin as the unit of length.[9][10]

Etymology

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 Greek word is derived from the Proto-Indo-European root *meh₁- 'to measure'. 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. The use of the word metre (for the French unit mètre) in English began at least as early as 1797.[11]

History of definition

Main article: History of the metre
 
Meridian room of the Paris Observatory (or Cassini room): the Paris meridian is drawn on the ground.

Pendulum or meridian

In 1671, Jean Picard measured the length of a "seconds pendulum" and proposed a unit of measurement twice that length to be called the universal toise (French: Toise universelle).[12][13] In 1675, Tito Livio Burattini suggested the term metre for a unit of length based on a pendulum length, but then it was discovered that the length of a seconds pendulum varies from place to place.[14][15][16][17][18][19][20][21][22]

Since Eratosthenes, geographers had used meridian arcs to assess the size of the Earth, which in 1669, Jean Picard determined to have a radius of 3269000 toises, treated as a simple sphere. In the 18th century, geodesy grew in importance as a means of empirically demonstrating the theory of gravity, which Émilie du Châtelet promoted in France in combination with Leibniz mathematical work,[23] and because the radius of the Earth was the unit to which all celestial distances were to be referred.[24][25][26]

Meridional definition

As a result of the Lumières and during 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 quarter meridian, the distance between the North Pole and the Equator along the meridian through Paris.[27][28][29][30][31] On 26 March 1791, the French National Constituent Assembly adopted the proposal.[11][32]

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 at the longitude of the Paris Panthéon (see meridian arc of Delambre and Méchain).[33] The expedition was fictionalised in Denis Guedj, Le Mètre du Monde.[34] Ken Alder wrote factually about the expedition in The Measure of All Things: the seven year odyssey and hidden error that transformed the world.[35] This portion of the Paris meridian was to serve as the basis for the length of the half meridian connecting the North Pole with the Equator. From 1801 to 1812 France adopted this definition of the metre as its official unit of length based on results from this expedition combined with those of the Geodesic Mission to Peru.[36][37] The latter was related by Larrie D. Ferreiro in Measure of the Earth: The Enlightenment Expedition that Reshaped Our World.[38][39]

In the 19th century, geodesy underwent a revolution through advances in mathematics as well as improvements in the instruments and methods of observation, for instance accounting for individual bias in terms of the personal equation. The application of the least squares method to meridian arc measurements demonstrated the importance of the scientific method in geodesy. On the other hand, the invention of the telegraph made it possible to measure parallel arcs, and the improvement of the reversible pendulum gave rise to the study of the Earth's gravitational field. A more accurate determination of the Figure of the Earth would soon result from the measurement of the Struve Geodetic Arc (1816–1855) and would have given another value for the definition of this standard of length. This did not invalidate the metre but highlighted that progress in science would allow better measurement of Earth's size and shape.[40][41][42][43]

In 1832, Carl Friedrich Gauss studied the Earth's magnetic field and proposed adding the second to the basic units of the metre and the kilogram in the form of the CGS system (centimetre, gram, second). In 1836, he founded the Magnetischer Verein, the first international scientific association, in collaboration with Alexander von Humboldt and Wilhelm Edouard Weber. The coordination of the observation of geophysical phenomena such as the Earth's magnetic field, lightning and gravity in different points of the globe stimulated the creation of the first international scientific associations. The foundation of the Magnetischer Verein would be followed by that of the Central European Arc Measurement (German: Mitteleuropaïsche Gradmessung) on the initiative of Johann Jacob Baeyer in 1863, and by that of the International Meteorological Organisation whose second president, the Swiss meteorologist and physicist, Heinrich von Wild would represent Russia at the International Committee for Weights and Measures (CIPM).[44][45][46][47][48][49]

International prototype metre bar

The influence of the intellect transcends mountains and leaps across oceans. At the time when George Washington warned his fellow countrymen against entangling political alliances with European countries, there was started a movement of far reaching importance in a small country in the heart of the Alps which (as we shall see) exerted a silent, yet potent scientific influence upon the young republic on the eastern shores of North America.

— Florian Cajori[50]
 
Triangulation near New York City, 1817.

In 1816, Ferdinand Rudolph Hassler was appointed first Superintendent of the Survey of the Coast. Trained in geodesy in Switzerland, France and Germany, Hassler had brought a standard metre made in Paris to the United States in 1805. He designed a baseline apparatus which instead of bringing different bars in actual contact during measurements, used only one bar calibrated on the metre and optical contact. Thus the metre became the unit of length for geodesy in the United States.[51][52][53][54]

Since 1830, Hassler was also head of the Bureau of Weights and Measures which became a part of the Coast Survey. He compared various units of length used in the United States at that time and measured coefficients of expansion to assess temperature effects on the measurements.[55]

In 1841, Friedrich Wilhelm Bessel, taking into account errors which had been recognized by Louis Puissant in the French meridian arc comprising the arc measurement of Delambre and Méchain which had been extended southward by François Arago and Jean-Baptiste Biot, recalculated the flattening of the Earth ellipsoid making use of nine more arc measurements, namely Peruan, Prussian, first East-Indian, second East-Indian, English, Hannover, Danish, Russian and Swedish covering almost 50 degrees of latitude, and stated that the Earth quadrant used for determining the length of the metre was nothing more than a rather imprecise conversion factor between the toise and the metre.[56][57][58]

Regarding the precision of the conversion from the toise to the metre, both units of measurement were then defined by primary standards, and unique artifacts made of different alloys with distinct coefficients of expansion were the legal basis of units of length. A wrought iron ruler, the Toise of Peru, also called Toise de l'Académie, was the French primary standard of the toise, and the metre was officially defined by the Mètre des Archives made of platinum. Besides the latter, another platinum and twelve iron standards of the metre were made in 1799. One of them became known as the Committee Meter in the United States and served as standard of length in the Coast Survey until 1890. According to geodesists, these standards were secondary standards deduced from the Toise of Peru. In Europe, surveyors continued to use measuring instruments calibrated on the Toise of Peru. Among these, the toise of Bessel and the apparatus of Borda were respectively the main references for geodesy in Prussia and in France. A French scientific instrument maker, Jean Nicolas Fortin, had made two direct copies of the Toise of Peru, the first for Friedrich Georg Wilhelm von Struve in 1821 and a second for Friedrich Bessel in 1823.[59][54][49][60][61]

On the subject of the theoretical definition of the metre, it had been inaccessible and misleading at the time of Delambre and Mechain arc measurement, as the geoid is a ball, which on the whole can be assimilated to an oblate spheroid, but which in detail differs from it so as to prohibit any generalization and any extrapolation. As early as 1861, after Friedrich von Schubert showed that the different meridians were not of equal length, Elie Ritter, a mathematician from Geneva, deduced from a computation based on eleven meridian arcs covering 86 degrees that the meridian equation differed from that of the ellipse: the meridian was swelled about the 45th degree of latitude by a layer whose thickness was difficult to estimate because of the uncertainty of the latitude of some stations, in particular that of Montjuïc in the French meridian arc. By measuring the latitude of two stations in Barcelona, Méchain had found that the difference between these latitudes was greater than predicted by direct measurement of distance by triangulation. We know now that, in addition to other errors in the survey of Delambre and Méchain, an unfavourable vertical deflection gave an inaccurate determination of Barcelona's latitude, a metre "too short" compared to a more general definition taken from the average of a large number of arcs.[62][63][58][64][65]

Nevertheless Ferdinand Rudolph Hassler's use of the metre in coastal survey contributed to the introduction of the Metric Act of 1866 allowing the use of the metre in the United States, and also played an important role in the choice of the metre as international scientific unit of length and the proposal by the European Arc Measurement (German: Europäische Gradmessung) to “establish a European international bureau for weights and measures”. However, in 1866, the most important concern was that the Toise of Peru, the standard of the toise constructed in 1735 for the French Geodesic Mission to the Equator, might be so much damaged that comparison with it would be worthless, while Bessel had questioned the accuracy of copies of this standard belonging to Altona and Koenigsberg Observatories, which he had compared to each other about 1840. Indeed when the primary Imperial yard standard was partially destroyed in 1834, a new standard of reference had been constructed using copies of the "Standard Yard, 1760" instead of the pendulum's length as provided for in the Weights and Measures Act of 1824.[66][67][68][60][69][70][71]

In 1864, Urbain Le Verrier refused to join the first general conference of the Central European Arc Measurement because the French geodetic works had to be verified.[72]

 
Swiss baseline measurement with Ibáñez apparatus in 1880.

In 1866, at the meeting of the Permanent Commission of the association in Neuchâtel, Antoine Yvon Villarceau announced that he had checked eight points of the French arc. He confirmed that the metre was too short. It then became urgent to undertake a complete revision of the meridian arc. Moreover, while the extension of the French meridian arc to the Balearic Islands (1803–1807) had seemed to confirm the length of the metre, this survey had not been secured by any baseline in Spain. For that reason, Carlos Ibáñez e Ibáñez de Ibero's announcement, at this conference, of his 1858 measurement of a baseline in Madridejos was of particular importance. Indeed surveyors determined the size of triangulation networks by measuring baselines which concordance granted the accuracy of the whole survey.[73][58][74][75][62]

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.[76][77][78] The conference recommended the adoption of the metre in replacement of the toise 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 who had devised two geodetic standards calibrated on the metre for the map of Spain.[79][76][78][80]

Ibáñez adopted the system which Ferdinand Rudolph Hassler used for the United States Survey of the Coast, consisting of a single standard with lines marked on the bar and microscopic measurements. Regarding the two methods by which the effect of temperature was taken into account, Ibáñez used both the bimetallic rulers, in platinum and brass, which he first employed for the central baseline of Spain, and the simple iron ruler with inlaid mercury thermometers which was utilized in Switzerland. These devices, the first of which is referred to as either Brunner apparatus or Spanish Standard, were constructed in France by Jean Brunner, then his sons. Measurement traceability between the toise and the metre was ensured by comparison of the Spanish Standard with the standard devised by Borda and Lavoisier for the survey of the meridian arc connecting Dunkirk with Barcelona.[81][80][82][76][83][84][24][85][86]

Hassler's metrological and geodetic work also had a favourable response in Russia.[55] In 1869, the Saint Petersburg Academy of Sciences sent to the French Academy of Sciences a report drafted by Otto Wilhelm von Struve, Heinrich von Wild and Moritz von Jacobi inviting his French counterpart to undertake joint action to ensure the universal use of the metric system in all scientific work.[71]

 
Creating the metre-alloy in 1874 at the Conservatoire des Arts et Métiers. Present Henri Tresca, George Matthey, Saint-Claire Deville and Debray

In the 1870s and in light of modern precision, a series of international conferences was held to devise new metric standards. When a conflict broke out regarding the presence of impurities in the metre-alloy of 1874, a member of the Preparatory Committee since 1870 and Spanish representative at the Paris Conference in 1875, Carlos Ibáñez e Ibáñez de Ibero intervened with the French Academy of Sciences to rally France to the project to create an International Bureau of Weights and Measures equipped with the scientific means necessary to redefine the units of the metric system according to the progress of sciences.[87][88][49][89]

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 distributed such bars 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.[87]

 
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

The comparison of the new prototypes of the metre with each other and with the Committee metre (French: Mètre des Archives) involved the development of special measuring equipment and the definition of a reproducible temperature scale. The BIPM's thermometry work led to the discovery of special alloys of iron-nickel, in particular invar, for which its director, the Swiss physicist Charles-Edouard Guillaume, was granted the Nobel Prize for physics in 1920.[90]

 
Gravimeter with variant of Repsold-Bessel pendulum

As Carlos Ibáñez e Ibáñez de Ibero stated, the progress of metrology combined with those of gravimetry through improvement of Kater's pendulum led to a new era of geodesy. If precision metrology had needed the help of geodesy, the latter could not continue to prosper without the help of metrology. It was then necessary to define a single unit to express all the measurements of terrestrial arcs and all determinations of the force of gravity by the mean of pendulum. Metrology had to create a common unit, adopted and respected by all civilized nations.[41]

Moreover, at that time, statisticians knew that scientific observations are marred by two distinct types of errors, constant errors on the one hand, and fortuitous errors, on the other hand. The effects of the latters can be mitigated by the least-squares method. Constant or regular errors on the contrary must be carefully avoided, because they arise from one or more causes that constantly act in the same way and have the effect of always altering the result of the experiment in the same direction. They therefore deprive of any value the observations that they impinge. However, the distinction between systematic and random errors is far from being as sharp as one might think at first assessment. In reality, there are no or very few random errors. As science progresses, the causes of certain errors are sought out, studied, their laws discovered. These errors pass from the class of random errors into that of systematic errors. The ability of the observer consists in discovering the greatest possible number of systematic errors in order to be able, once he has become acquainted with their laws, to free his results from them using a method or appropriate corrections.[91][92]

For metrology the matter of expansibility was fundamental; as a matter of fact the temperature measuring error related to the length measurement in proportion to the expansibility of the standard and the constantly renewed efforts of metrologists to protect their measuring instruments against the interfering influence of temperature revealed clearly the importance they attached to the expansion-induced errors. It was thus crucial to compare at controlled temperatures with great precision and to the same unit all the standards for measuring geodetic baselines and all the pendulum rods. Only when this series of metrological comparisons would be finished with a probable error of a thousandth of a millimetre would geodesy be able to link the works of the different nations with one another, and then proclaim the result of the measurement of the Globe.[93][41]

As the figure of the Earth could be inferred from variations of the seconds pendulum length with latitude, the United States Coast Survey instructed Charles Sanders Peirce in the spring of 1875 to proceed to Europe for the purpose of making pendulum experiments to chief initial stations for operations of this sort, in order to bring the determinations of the forces of gravity in America into communication with those of other parts of the world; and also for the purpose of making a careful study of the methods of pursuing these researches in the different countries of Europe. In 1886 the association of geodesy changed name for the International Geodetic Association, which Carlos Ibáñez e Ibáñez de Ibero presided up to his death in 1891. During this period the International Geodetic Association (German: Internationale Erdmessung) gained worldwide importance with the joining of United States, Mexico, Chile, Argentina and Japan.[81][94][95][96][97]

 
Artist's impression of a GPS-IIR satellite in orbit.

Efforts to supplement the various national surveying systems, which began in the 19th century with the foundation of the Mitteleuropäische Gradmessung, resulted in a series of global ellipsoids of the Earth (e.g., Helmert 1906, Hayford 1910 and 1924) which would later lead to develop the World Geodetic System. Nowadays the practical realisation of the metre is possible everywhere thanks to the atomic clocks embedded in GPS satellites.[98][99]

Wavelength definition

In 1873, James Clerk Maxwell suggested that light emitted by an element be used as the standard both for the metre and for the second. These two quantities could then be used to define the unit of mass.[100]

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 1650763.73 wavelengths of the orange-red emission line in the electromagnetic spectrum of the krypton-86 atom in a vacuum.[101]

Speed of light definition

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:[102][103]

The metre is the length of the path travelled by light in vacuum during a time interval of 1/299792458 of a second.

This definition fixed the speed of light in vacuum at exactly 299792458 metres per second[102] (≈300000 km/s or ≈1.079 billion km/hour[104]). 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.[105] For the purpose of delineating the metre, the BIPM currently considers the HeNe laser wavelength, λHeNe, to be 632.99121258 nm with an estimated relative standard uncertainty (U) of 2.1×10−11.[105][106][107] 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 = 5×10−16).[108] Consequently, a realisation of the metre is usually delineated (not defined) today in labs as 1579800.762042(33) wavelengths of helium-neon laser light in a vacuum, the error stated being only that of frequency determination.[105] 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.[109] 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.[110] 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.[111] 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 1579800.762042(33) wavelengths of helium–neon laser light in a vacuum, and converting the wavelengths in a vacuum to wavelengths in air. 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.[112]

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,[115] and converting the selected unit of wavelength to metres. Three major factors limit the accuracy attainable with laser interferometers for a length measurement:[109][116]

  • 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

 

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.[116]

The CIPM issued a clarification in 2002:

Its definition, therefore, applies only within a spatial extent sufficiently small that the effects of the non-uniformity of the gravitational field can be ignored (note that, at the surface of the Earth, this effect in the vertical direction is about 1 part in 1016 per metre). In this case, the effects to be taken into account are those of special relativity only.

Timeline

Date Deciding body Decision
8 May 1790 French National Assembly The length of the new metre to be equal to the length of a pendulum with a half-period of one second.[36]
30 Mar 1791 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 great circle quadrant along the Earth's meridian through Paris, that is the distance from the equator to the north pole along that quadrant.[117]
1795 Provisional metre bar made of brass and based on Paris meridan arc (French: Méridienne de France) measured by Nicolas-Louis de Lacaillle and Cesar-François Cassini de Thury, legally equal to 443.44 lines of the toise du Pérou (a standard French unit of length from 1766).[36][37][82][99] [The line was 1/864 of a toise.]
10 Dec 1799 French National Assembly Specifies the platinum metre bar, presented on 22 June 1799 and deposited in the National Archives, as the final standard. Legally equal to 443.296 lines on the toise du Pérou.[99]
24–28 Sept 1889 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.[99][118]
27 Sept – 6 Oct 1927 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.[119]
14 Oct 1960 11th CGPM Defines the metre as 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.[120]
21 Oct 1983 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.[121][122]
2002 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".[123]
Definitions of the metre since 1795[124]
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 10−4
First prototype Mètre des Archives platinum bar standard 1799 50–10 μm 10−5
Platinum-iridium bar at melting point of ice (1st CGPM) 1889 0.2–0.1 μm (200–100 nm) 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; 1650763.73 wavelengths of light from a specified transition in krypton-86 (11th CGPM) 1960 4 nm 4×10−9[125]
Length of the path travelled by light in a vacuum in 1/299 792 458 second (17th CGPM) 1983 0.1 nm 10−10

Early adoptions of the metre internationally

Main article: Metrication

In France, the metre was adopted as an exclusive measure in 1801 under the Consulate. This continued under the First French Empire until 1812, when Napoleon decreed the introduction of the non-decimal mesures usuelles, which remained in use in France up to 1840 in the reign of Louis Philippe.[36] Meanwhile, the metre was adopted by the Republic of Geneva.[126] After the joining of the canton of Geneva to Switzerland in 1815, Guillaume Henri Dufour published the first official Swiss map, for which the metre was adopted as the unit of length.[127][128] Louis Napoléon Bonaparte, a Swiss–French binational officer, was present when a baseline was measured near Zürich for the Dufour map, which would win the gold medal for a national map at the Exposition Universelle of 1855.[129][130][131] Among the scientific instruments calibrated on the metre that were displayed at the Exposition Universelle, was Brunner's apparatus, a geodetic instrument devised for measuring the central baseline of Spain, whose designer, Carlos Ibáñez e Ibáñez de Ibero would represent Spain at the International Statistical Institute. In 1885, in addition to the Exposition Universelle and the second Statistical Congress held in Paris, an International Association for Obtaining a Uniform Decimal System of Measures, Weights, and Coins was created there.[49][132][133][134] Copies of the Spanish standard were made for Egypt, France and Germany.[135][136][137] These standards were compared to each other and with the Borda apparatus, which was the main reference for measuring all geodetic bases in France.[135][86][81] In 1869, Napoleon III convened the International Metre Commission, which was to meet in Paris in 1870. The Franco-Prussian War broke out, the Second French Empire collapsed, but the metre survived.[138][68]

Metre adoption dates by country

SI prefixed forms of metre

Main article: Orders of magnitude (length)

SI prefixes can be used to denote decimal multiples and submultiples of the metre, as shown in the table below. 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 millimicron can be used instead of micrometre (μm) and nanometre (nm), but this practice may be discouraged.[140]


SI multiples of metre (m)
Submultiples Multiples
Value SI symbol Name Value SI symbol Name
10−1 m dm decimetre 101 m dam decametre
10−2 m cm centimetre 102 m hm hectometre
10−3 m mm millimetre 103 m km kilometre
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
10−27 m rm rontometre 1027 m Rm ronnametre
10−30 m qm quectometre 1030 m Qm quettametre

Equivalents in other units

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 0.39370 inch 1 inch = 2.54 centimetres
1 millimetre 0.039370 inch 1 inch = 25.4 millimetres
1 metre = 1010 ångström 1 ångström = 10−10 metre
1 nanometre = 10 ångström 1 ångström = 100 picometres

Within this table, "inch" and "yard" mean "international inch" and "international yard"[141] respectively, though approximate conversions in the left column hold for both international and survey units.

"≈" means "is approximately equal to";
"=" means "is exactly equal to".

One metre is exactly equivalent to 5 000/127 inches and to 1 250/1 143 yards.

A simple mnemonic aid exists to assist with conversion, as three "3"s:

1 metre is nearly equivalent to 3 feet 3+38 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).[142] Scottish and English definitions of the ell (two cubits) were 941 mm (0.941 m) and 1143 mm (1.143 m) respectively.[143][144] 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 12 toise.[145] The Russian verst was 1.0668 km.[146] The Swedish mil was 10.688 km, but was changed to 10 km when Sweden converted to metric units.[147]

See also

 
Wikimedia Commons has media related to Metre.
 
Look up metre in Wiktionary, the free dictionary.

Notes

  1. ^ "Base unit definitions: Meter". National Institute of Standards and Technology. Retrieved 28 September 2010.
  2. ^ "The International System of Units (SI) – NIST". US: National Institute of Standards and Technology. 26 March 2008. The spelling of English words is in accordance with the United States Government Printing Office Style Manual, which follows Webster's Third New International Dictionary rather than the Oxford Dictionary. Thus the spellings "meter,"…rather than "metre,"...as in the original BIPM English text...
  3. ^ 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. 130ff). 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".
  4. ^ Naughtin, Pat (2008). "Spelling metre or meter" (PDF). Metrication Matters. Retrieved 12 March 2017.
  5. ^ "Meter vs. metre". Grammarist. 21 February 2011. Retrieved 12 March 2017.
  6. ^ 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).
  7. ^ "295–296 (Nordisk familjebok / Uggleupplagan. 18. Mekaniker – Mykale)" [295–296 (Nordic Family Book / Owl Edition. 18. Mechanic – Mycular)]. Stockholm. 1913.
  8. ^ Cambridge Advanced Learner's Dictionary. Cambridge University Press. 2008. Retrieved 19 September 2012., s.v. ammeter, meter, parking meter, speedometer.
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References

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January 26, 2023
metre, this, article, about, unit, length, other, uses, metre, meter, meter, disambiguation, metre, british, spelling, meter, american, spelling, spelling, differences, from, french, unit, mètre, from, greek, noun, μέτρον, measure, symbol, primary, unit, lengt. This article is about the unit of length For other uses of metre or meter see Meter disambiguation The metre British spelling or meter American spelling see spelling differences from the French unit metre from the Greek noun metron measure symbol m is the primary unit of length in the International System of Units SI though its prefixed forms are also used relatively frequently metreSeal of the International Bureau of Weights and Measures BIPM Use measure Greek METRW XRW General informationUnit systemSIUnit oflengthSymbolm 1 Conversions1 m 1 in is equal to SI units 1000 mm0 001 km Imperial US units 1 0936 yd 3 2808 ft 39 37 in Nautical units 0 000539 96 nmiThe metre was originally defined in 1793 as one ten millionth of the distance from the equator to the North Pole along a great circle so the Earth s circumference is approximately 40000 km In 1799 the metre 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 The current definition was adopted in 1983 and modified slightly in 2002 to clarify that the metre is a measure of proper length From 1983 until 2019 the metre was formally defined as the length of the path travelled by light in a vacuum in 1 299792 458 of a second After the 2019 redefinition of the SI base units this definition was rephrased to include the definition of a second in terms of the caesium frequency DnCs Contents 1 Spelling 2 Etymology 3 History of definition 3 1 Pendulum or meridian 3 2 Meridional definition 3 3 International prototype metre bar 3 4 Wavelength definition 3 5 Speed of light definition 3 6 Timeline 4 Early adoptions of the metre internationally 4 1 Metre adoption dates by country 5 SI prefixed forms of metre 6 Equivalents in other units 7 See also 8 Notes 9 ReferencesSpelling EditMetre is the standard spelling of the metric unit for length in nearly all English speaking nations except the United States 2 3 4 5 and the Philippines 6 which use meter Other West Germanic languages such as German and Dutch and North Germanic languages such as Danish Norwegian and Swedish 7 likewise spell the word Meter or meter Measuring devices such as ammeter speedometer are spelled meter in all variants of English 8 The suffix meter has the same Greek origin as the unit of length 9 10 Etymology EditThe etymological roots of metre can be traced to the Greek verb metrew metreo to measure count or compare and noun metron 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 metre mesure English and other languages The Greek word is derived from the Proto Indo European root meh to measure The motto METRW XRW 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 The use of the word metre for the French unit metre in English began at least as early as 1797 11 History of definition EditMain article History of the metre Meridian room of the Paris Observatory or Cassini room the Paris meridian is drawn on the ground Pendulum or meridian Edit In 1671 Jean Picard measured the length of a seconds pendulum and proposed a unit of measurement twice that length to be called the universal toise French Toise universelle 12 13 In 1675 Tito Livio Burattini suggested the term metre for a unit of length based on a pendulum length but then it was discovered that the length of a seconds pendulum varies from place to place 14 15 16 17 18 19 20 21 22 Since Eratosthenes geographers had used meridian arcs to assess the size of the Earth which in 1669 Jean Picard determined to have a radius of 3269 000 toises treated as a simple sphere In the 18th century geodesy grew in importance as a means of empirically demonstrating the theory of gravity which Emilie du Chatelet promoted in France in combination with Leibniz mathematical work 23 and because the radius of the Earth was the unit to which all celestial distances were to be referred 24 25 26 Meridional definition Edit Paris Pantheon As a result of the Lumieres and during 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 metre measure a basic unit of length which they defined as equal to one ten millionth of the quarter meridian the distance between the North Pole and the Equator along the meridian through Paris 27 28 29 30 31 On 26 March 1791 the French National Constituent Assembly adopted the proposal 11 32 The French Academy of Sciences commissioned an expedition led by Jean Baptiste Joseph Delambre and Pierre Mechain lasting from 1792 to 1799 which attempted to accurately measure the distance between a belfry in Dunkerque and Montjuic castle in Barcelona at the longitude of the Paris Pantheon see meridian arc of Delambre and Mechain 33 The expedition was fictionalised in Denis Guedj Le Metre du Monde 34 Ken Alder wrote factually about the expedition in The Measure of All Things the seven year odyssey and hidden error that transformed the world 35 This portion of the Paris meridian was to serve as the basis for the length of the half meridian connecting the North Pole with the Equator From 1801 to 1812 France adopted this definition of the metre as its official unit of length based on results from this expedition combined with those of the Geodesic Mission to Peru 36 37 The latter was related by Larrie D Ferreiro in Measure of the Earth The Enlightenment Expedition that Reshaped Our World 38 39 In the 19th century geodesy underwent a revolution through advances in mathematics as well as improvements in the instruments and methods of observation for instance accounting for individual bias in terms of the personal equation The application of the least squares method to meridian arc measurements demonstrated the importance of the scientific method in geodesy On the other hand the invention of the telegraph made it possible to measure parallel arcs and the improvement of the reversible pendulum gave rise to the study of the Earth s gravitational field A more accurate determination of the Figure of the Earth would soon result from the measurement of the Struve Geodetic Arc 1816 1855 and would have given another value for the definition of this standard of length This did not invalidate the metre but highlighted that progress in science would allow better measurement of Earth s size and shape 40 41 42 43 In 1832 Carl Friedrich Gauss studied the Earth s magnetic field and proposed adding the second to the basic units of the metre and the kilogram in the form of the CGS system centimetre gram second In 1836 he founded the Magnetischer Verein the first international scientific association in collaboration with Alexander von Humboldt and Wilhelm Edouard Weber The coordination of the observation of geophysical phenomena such as the Earth s magnetic field lightning and gravity in different points of the globe stimulated the creation of the first international scientific associations The foundation of the Magnetischer Verein would be followed by that of the Central European Arc Measurement German Mitteleuropaische Gradmessung on the initiative of Johann Jacob Baeyer in 1863 and by that of the International Meteorological Organisation whose second president the Swiss meteorologist and physicist Heinrich von Wild would represent Russia at the International Committee for Weights and Measures CIPM 44 45 46 47 48 49 International prototype metre bar Edit The influence of the intellect transcends mountains and leaps across oceans At the time when George Washington warned his fellow countrymen against entangling political alliances with European countries there was started a movement of far reaching importance in a small country in the heart of the Alps which as we shall see exerted a silent yet potent scientific influence upon the young republic on the eastern shores of North America Florian Cajori 50 Triangulation near New York City 1817 In 1816 Ferdinand Rudolph Hassler was appointed first Superintendent of the Survey of the Coast Trained in geodesy in Switzerland France and Germany Hassler had brought a standard metre made in Paris to the United States in 1805 He designed a baseline apparatus which instead of bringing different bars in actual contact during measurements used only one bar calibrated on the metre and optical contact Thus the metre became the unit of length for geodesy in the United States 51 52 53 54 Since 1830 Hassler was also head of the Bureau of Weights and Measures which became a part of the Coast Survey He compared various units of length used in the United States at that time and measured coefficients of expansion to assess temperature effects on the measurements 55 In 1841 Friedrich Wilhelm Bessel taking into account errors which had been recognized by Louis Puissant in the French meridian arc comprising the arc measurement of Delambre and Mechain which had been extended southward by Francois Arago and Jean Baptiste Biot recalculated the flattening of the Earth ellipsoid making use of nine more arc measurements namely Peruan Prussian first East Indian second East Indian English Hannover Danish Russian and Swedish covering almost 50 degrees of latitude and stated that the Earth quadrant used for determining the length of the metre was nothing more than a rather imprecise conversion factor between the toise and the metre 56 57 58 Regarding the precision of the conversion from the toise to the metre both units of measurement were then defined by primary standards and unique artifacts made of different alloys with distinct coefficients of expansion were the legal basis of units of length A wrought iron ruler the Toise of Peru also called Toise de l Academie was the French primary standard of the toise and the metre was officially defined by the Metre des Archives made of platinum Besides the latter another platinum and twelve iron standards of the metre were made in 1799 One of them became known as the Committee Meter in the United States and served as standard of length in the Coast Survey until 1890 According to geodesists these standards were secondary standards deduced from the Toise of Peru In Europe surveyors continued to use measuring instruments calibrated on the Toise of Peru Among these the toise of Bessel and the apparatus of Borda were respectively the main references for geodesy in Prussia and in France A French scientific instrument maker Jean Nicolas Fortin had made two direct copies of the Toise of Peru the first for Friedrich Georg Wilhelm von Struve in 1821 and a second for Friedrich Bessel in 1823 59 54 49 60 61 On the subject of the theoretical definition of the metre it had been inaccessible and misleading at the time of Delambre and Mechain arc measurement as the geoid is a ball which on the whole can be assimilated to an oblate spheroid but which in detail differs from it so as to prohibit any generalization and any extrapolation As early as 1861 after Friedrich von Schubert showed that the different meridians were not of equal length Elie Ritter a mathematician from Geneva deduced from a computation based on eleven meridian arcs covering 86 degrees that the meridian equation differed from that of the ellipse the meridian was swelled about the 45th degree of latitude by a layer whose thickness was difficult to estimate because of the uncertainty of the latitude of some stations in particular that of Montjuic in the French meridian arc By measuring the latitude of two stations in Barcelona Mechain had found that the difference between these latitudes was greater than predicted by direct measurement of distance by triangulation We know now that in addition to other errors in the survey of Delambre and Mechain an unfavourable vertical deflection gave an inaccurate determination of Barcelona s latitude a metre too short compared to a more general definition taken from the average of a large number of arcs 62 63 58 64 65 Nevertheless Ferdinand Rudolph Hassler s use of the metre in coastal survey contributed to the introduction of the Metric Act of 1866 allowing the use of the metre in the United States and also played an important role in the choice of the metre as international scientific unit of length and the proposal by the European Arc Measurement German Europaische Gradmessung to establish a European international bureau for weights and measures However in 1866 the most important concern was that the Toise of Peru the standard of the toise constructed in 1735 for the French Geodesic Mission to the Equator might be so much damaged that comparison with it would be worthless while Bessel had questioned the accuracy of copies of this standard belonging to Altona and Koenigsberg Observatories which he had compared to each other about 1840 Indeed when the primary Imperial yard standard was partially destroyed in 1834 a new standard of reference had been constructed using copies of the Standard Yard 1760 instead of the pendulum s length as provided for in the Weights and Measures Act of 1824 66 67 68 60 69 70 71 In 1864 Urbain Le Verrier refused to join the first general conference of the Central European Arc Measurement because the French geodetic works had to be verified 72 Swiss baseline measurement with Ibanez apparatus in 1880 In 1866 at the meeting of the Permanent Commission of the association in Neuchatel Antoine Yvon Villarceau announced that he had checked eight points of the French arc He confirmed that the metre was too short It then became urgent to undertake a complete revision of the meridian arc Moreover while the extension of the French meridian arc to the Balearic Islands 1803 1807 had seemed to confirm the length of the metre this survey had not been secured by any baseline in Spain For that reason Carlos Ibanez e Ibanez de Ibero s announcement at this conference of his 1858 measurement of a baseline in Madridejos was of particular importance Indeed surveyors determined the size of triangulation networks by measuring baselines which concordance granted the accuracy of the whole survey 73 58 74 75 62 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 76 77 78 The conference recommended the adoption of the metre in replacement of the toise and the creation of an international metre commission according to the proposal of Johann Jacob Baeyer Adolphe Hirsch and Carlos Ibanez e Ibanez de Ibero who had devised two geodetic standards calibrated on the metre for the map of Spain 79 76 78 80 Ibanez adopted the system which Ferdinand Rudolph Hassler used for the United States Survey of the Coast consisting of a single standard with lines marked on the bar and microscopic measurements Regarding the two methods by which the effect of temperature was taken into account Ibanez used both the bimetallic rulers in platinum and brass which he first employed for the central baseline of Spain and the simple iron ruler with inlaid mercury thermometers which was utilized in Switzerland These devices the first of which is referred to as either Brunner apparatus or Spanish Standard were constructed in France by Jean Brunner then his sons Measurement traceability between the toise and the metre was ensured by comparison of the Spanish Standard with the standard devised by Borda and Lavoisier for the survey of the meridian arc connecting Dunkirk with Barcelona 81 80 82 76 83 84 24 85 86 Hassler s metrological and geodetic work also had a favourable response in Russia 55 In 1869 the Saint Petersburg Academy of Sciences sent to the French Academy of Sciences a report drafted by Otto Wilhelm von Struve Heinrich von Wild and Moritz von Jacobi inviting his French counterpart to undertake joint action to ensure the universal use of the metric system in all scientific work 71 Creating the metre alloy in 1874 at the Conservatoire des Arts et Metiers Present Henri Tresca George Matthey Saint Claire Deville and Debray In the 1870s and in light of modern precision a series of international conferences was held to devise new metric standards When a conflict broke out regarding the presence of impurities in the metre alloy of 1874 a member of the Preparatory Committee since 1870 and Spanish representative at the Paris Conference in 1875 Carlos Ibanez e Ibanez de Ibero intervened with the French Academy of Sciences to rally France to the project to create an International Bureau of Weights and Measures equipped with the scientific means necessary to redefine the units of the metric system according to the progress of sciences 87 88 49 89 The Metre Convention Convention du Metre 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 Sevres 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 distributed such bars in 1889 at the first General Conference on Weights and Measures CGPM Conference Generale 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 87 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 The comparison of the new prototypes of the metre with each other and with the Committee metre French Metre des Archives involved the development of special measuring equipment and the definition of a reproducible temperature scale The BIPM s thermometry work led to the discovery of special alloys of iron nickel in particular invar for which its director the Swiss physicist Charles Edouard Guillaume was granted the Nobel Prize for physics in 1920 90 Gravimeter with variant of Repsold Bessel pendulum As Carlos Ibanez e Ibanez de Ibero stated the progress of metrology combined with those of gravimetry through improvement of Kater s pendulum led to a new era of geodesy If precision metrology had needed the help of geodesy the latter could not continue to prosper without the help of metrology It was then necessary to define a single unit to express all the measurements of terrestrial arcs and all determinations of the force of gravity by the mean of pendulum Metrology had to create a common unit adopted and respected by all civilized nations 41 Moreover at that time statisticians knew that scientific observations are marred by two distinct types of errors constant errors on the one hand and fortuitous errors on the other hand The effects of the latters can be mitigated by the least squares method Constant or regular errors on the contrary must be carefully avoided because they arise from one or more causes that constantly act in the same way and have the effect of always altering the result of the experiment in the same direction They therefore deprive of any value the observations that they impinge However the distinction between systematic and random errors is far from being as sharp as one might think at first assessment In reality there are no or very few random errors As science progresses the causes of certain errors are sought out studied their laws discovered These errors pass from the class of random errors into that of systematic errors The ability of the observer consists in discovering the greatest possible number of systematic errors in order to be able once he has become acquainted with their laws to free his results from them using a method or appropriate corrections 91 92 For metrology the matter of expansibility was fundamental as a matter of fact the temperature measuring error related to the length measurement in proportion to the expansibility of the standard and the constantly renewed efforts of metrologists to protect their measuring instruments against the interfering influence of temperature revealed clearly the importance they attached to the expansion induced errors It was thus crucial to compare at controlled temperatures with great precision and to the same unit all the standards for measuring geodetic baselines and all the pendulum rods Only when this series of metrological comparisons would be finished with a probable error of a thousandth of a millimetre would geodesy be able to link the works of the different nations with one another and then proclaim the result of the measurement of the Globe 93 41 As the figure of the Earth could be inferred from variations of the seconds pendulum length with latitude the United States Coast Survey instructed Charles Sanders Peirce in the spring of 1875 to proceed to Europe for the purpose of making pendulum experiments to chief initial stations for operations of this sort in order to bring the determinations of the forces of gravity in America into communication with those of other parts of the world and also for the purpose of making a careful study of the methods of pursuing these researches in the different countries of Europe In 1886 the association of geodesy changed name for the International Geodetic Association which Carlos Ibanez e Ibanez de Ibero presided up to his death in 1891 During this period the International Geodetic Association German Internationale Erdmessung gained worldwide importance with the joining of United States Mexico Chile Argentina and Japan 81 94 95 96 97 Artist s impression of a GPS IIR satellite in orbit Efforts to supplement the various national surveying systems which began in the 19th century with the foundation of the Mitteleuropaische Gradmessung resulted in a series of global ellipsoids of the Earth e g Helmert 1906 Hayford 1910 and 1924 which would later lead to develop the World Geodetic System Nowadays the practical realisation of the metre is possible everywhere thanks to the atomic clocks embedded in GPS satellites 98 99 Wavelength definition Edit In 1873 James Clerk Maxwell suggested that light emitted by an element be used as the standard both for the metre and for the second These two quantities could then be used to define the unit of mass 100 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 1650 763 73 wavelengths of the orange red emission line in the electromagnetic spectrum of the krypton 86 atom in a vacuum 101 Speed of light definition Edit 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 102 103 The metre is the length of the path travelled by light in vacuum during a time interval of 1 299792 458 of a second dd This definition fixed the speed of light in vacuum at exactly 299792 458 metres per second 102 300000 km s or 1 079 billion km hour 104 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 105 For the purpose of delineating the metre the BIPM currently considers the HeNe laser wavelength lHeNe to be 632 991212 58 nm with an estimated relative standard uncertainty U of 2 1 10 11 105 106 107 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 5 10 16 108 Consequently a realisation of the metre is usually delineated not defined today in labs as 1579 800 762042 33 wavelengths of helium neon laser light in a vacuum the error stated being only that of frequency determination 105 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 109 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 110 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 111 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 1579 800 762042 33 wavelengths of helium neon laser light in a vacuum and converting the wavelengths in a vacuum to wavelengths in air 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 112 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 115 and converting the selected unit of wavelength to metres Three major factors limit the accuracy attainable with laser interferometers for a length measurement 109 116 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 l c n f displaystyle lambda frac c nf which converts the unit of wavelength l 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 116 The CIPM issued a clarification in 2002 Its definition therefore applies only within a spatial extent sufficiently small that the effects of the non uniformity of the gravitational field can be ignored note that at the surface of the Earth this effect in the vertical direction is about 1 part in 1016 per metre In this case the effects to be taken into account are those of special relativity only Timeline Edit Date Deciding body Decision8 May 1790 French National Assembly The length of the new metre to be equal to the length of a pendulum with a half period of one second 36 30 Mar 1791 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 great circle quadrant along the Earth s meridian through Paris that is the distance from the equator to the north pole along that quadrant 117 1795 Provisional metre bar made of brass and based on Paris meridan arc French Meridienne de France measured by Nicolas Louis de Lacaillle and Cesar Francois Cassini de Thury legally equal to 443 44 lines of the toise du Perou a standard French unit of length from 1766 36 37 82 99 The line was 1 864 of a toise 10 Dec 1799 French National Assembly Specifies the platinum metre bar presented on 22 June 1799 and deposited in the National Archives as the final standard Legally equal to 443 296 lines on the toise du Perou 99 24 28 Sept 1889 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 99 118 27 Sept 6 Oct 1927 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 119 14 Oct 1960 11th CGPM Defines the metre as 1650 763 73 wavelengths in a vacuum of the radiation corresponding to the transition between the 2p10 and 5d5 quantum levels of the krypton 86 atom 120 21 Oct 1983 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 121 122 2002 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 123 Definitions of the metre since 1795 124 Basis of definition Date Absoluteuncertainty Relativeuncertainty1 10 000 000 part of the quadrant along the meridian measurement by Delambre and Mechain 443 296 lines 1795 500 100 mm 10 4First prototype Metre des Archives platinum bar standard 1799 50 10 mm 10 5Platinum iridium bar at melting point of ice 1st CGPM 1889 0 2 0 1 mm 200 100 nm 10 7Platinum iridium bar at melting point of ice atmospheric pressure supported by two rollers 7th CGPM 1927 n a n a Hyperfine atomic transition 1650 763 73 wavelengths of light from a specified transition in krypton 86 11th CGPM 1960 4 nm 4 10 9 125 Length of the path travelled by light in a vacuum in 1 299 792 458 second 17th CGPM 1983 0 1 nm 10 10Early adoptions of the metre internationally EditMain article MetricationIn France the metre was adopted as an exclusive measure in 1801 under the Consulate This continued under the First French Empire until 1812 when Napoleon decreed the introduction of the non decimal mesures usuelles which remained in use in France up to 1840 in the reign of Louis Philippe 36 Meanwhile the metre was adopted by the Republic of Geneva 126 After the joining of the canton of Geneva to Switzerland in 1815 Guillaume Henri Dufour published the first official Swiss map for which the metre was adopted as the unit of length 127 128 Louis Napoleon Bonaparte a Swiss French binational officer was present when a baseline was measured near Zurich for the Dufour map which would win the gold medal for a national map at the Exposition Universelle of 1855 129 130 131 Among the scientific instruments calibrated on the metre that were displayed at the Exposition Universelle was Brunner s apparatus a geodetic instrument devised for measuring the central baseline of Spain whose designer Carlos Ibanez e Ibanez de Ibero would represent Spain at the International Statistical Institute In 1885 in addition to the Exposition Universelle and the second Statistical Congress held in Paris an International Association for Obtaining a Uniform Decimal System of Measures Weights and Coins was created there 49 132 133 134 Copies of the Spanish standard were made for Egypt France and Germany 135 136 137 These standards were compared to each other and with the Borda apparatus which was the main reference for measuring all geodetic bases in France 135 86 81 In 1869 Napoleon III convened the International Metre Commission which was to meet in Paris in 1870 The Franco Prussian War broke out the Second French Empire collapsed but the metre survived 138 68 Metre adoption dates by country Edit France 1801 1812 then 1840 36 Republic of Geneva Switzerland 1813 139 Kingdom of the Netherlands 1820 Kingdom of Belgium 1830 Chile 1848 Kingdom of Sardinia Italy 1850 Spain 1852 Portugal 1852 Colombia 1853 Ecuador 1856 Mexico 1857 Brazil 1862 Argentina 1863 Italy 1863 German Empire Germany 1872 Austria 1875 Switzerland 1877 139 SI prefixed forms of metre EditMain article Orders of magnitude length SI prefixes can be used to denote decimal multiples and submultiples of the metre as shown in the table below 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 millimicron can be used instead of micrometre mm and nanometre nm but this practice may be discouraged 140 SI multiples of metre m Submultiples MultiplesValue SI symbol Name Value SI symbol Name10 1 m dm decimetre 101 m dam decametre10 2 m cm centimetre 102 m hm hectometre10 3 m mm millimetre 103 m km kilometre10 6 m µm micrometre 106 m Mm megametre10 9 m nm nanometre 109 m Gm gigametre10 12 m pm picometre 1012 m Tm terametre10 15 m fm femtometre 1015 m Pm petametre10 18 m am attometre 1018 m Em exametre10 21 m zm zeptometre 1021 m Zm zettametre10 24 m ym yoctometre 1024 m Ym yottametre10 27 m rm rontometre 1027 m Rm ronnametre10 30 m qm quectometre 1030 m Qm quettametreEquivalents in other units EditMetric unitexpressed in non SI units Non SI unitexpressed in metric units1 metre 1 0936 yard 1 yard 0 9144 metre1 metre 39 370 inches 1 inch 0 0254 metre1 centimetre 0 39370 inch 1 inch 2 54 centimetres1 millimetre 0 039370 inch 1 inch 25 4 millimetres1 metre 1010 angstrom 1 angstrom 10 10 metre1 nanometre 10 angstrom 1 angstrom 100 picometresWithin this table inch and yard mean international inch and international yard 141 respectively though approximate conversions in the left column hold for both international and survey units means is approximately equal to means is exactly equal to One metre is exactly equivalent to 5 000 127 inches and to 1 250 1 143 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 142 Scottish and English definitions of the ell two cubits were 941 mm 0 941 m and 1143 mm 1 143 m respectively 143 144 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 145 The Russian verst was 1 0668 km 146 The Swedish mil was 10 688 km but was changed to 10 km when Sweden converted to metric units 147 See also Edit Wikimedia Commons has media related to Metre Look up metre in Wiktionary the free dictionary Conversion of units for comparisons with other units International System of Units 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 Vertical metreNotes Edit Base unit definitions Meter National Institute of Standards and Technology Retrieved 28 September 2010 The International System of Units SI NIST US National Institute of Standards and Technology 26 March 2008 The spelling of English words is in accordance with the United States Government Printing Office Style Manual which follows Webster s Third New International Dictionary rather than the Oxford Dictionary Thus the spellings meter rather than metre as in the original BIPM English text 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 130ff 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 Systeme international d unites 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 21 February 2011 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 295 296 Nordisk familjebok Uggleupplagan 18 Mekaniker Mykale 295 296 Nordic Family Book Owl Edition 18 Mechanic Mycular Stockholm 1913 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 Archived from the original on 26 April 2017 a b Oxford English Dictionary Clarendon Press 2nd ed 1989 vol IX p 697 col 3 texte Picard Jean 1620 1682 Auteur du 1671 Mesure de la terre par l abbe Picard Gallica pp 3 4 Retrieved 13 September 2018 verification needed Bigourdan 1901 pp 8 158 159 Lucendo Jorge 23 April 2020 Centuries of Inventions Encyclopedia and History of Inventions Jorge Lucendo p 246 Retrieved 2 August 2021 Camerini Valentina 1 December 2020 365 Real Life Superheroes Black Inc p 292 ISBN 978 1 74382 138 1 Appendix B Tito Livio Burattini s catholic meter roma1 infn it Retrieved 3 August 2021 Science 1791 l adoption revolutionnaire du metre humanite fr in French 25 March 2021 Retrieved 3 August 2021 The meter an ingenious intuition from belluno Italiani Come Noi italianicomenoi it Retrieved 3 August 2021 Holtebekk Trygve 30 November 2020 Meter Store norske leksikon in Norwegian Bokmal Retrieved 3 August 2021 Poynting John Henry Thomson Joseph John 1907 A Textbook of Physics C Griffin pp 20 verification needed Picard Jean 1620 1682 Auteur du texte 1671 Mesure de la terre par l abbe Picard pp 3 5 Bond Peter 1948 2014 L exploration du systeme solaire Dupont Bloch Nicolas Edition francaise revue et corrigee ed Louvain la Neuve De Boeck pp 5 6 ISBN 9782804184964 OCLC 894499177 a href Template Cite book html title Template Cite book cite book a CS1 maint multiple names authors list link Touzery Mireille 3 July 2008 Emilie Du Chatelet un passeur scientifique au XVIIIe siecle La revue pour l histoire du CNRS in French 21 doi 10 4000 histoire cnrs 7752 ISSN 1298 9800 a b Clarke Alexander Ross Helmert Friedrich Robert 1911 Geodesy In Chisholm Hugh ed Encyclopaedia Britannica Vol 11 11th ed Cambridge University Press pp 607 615 Badinter Elisabeth 2018 Les passions intellectuelles Normandie roto impr Paris Robert Laffont ISBN 978 2 221 20345 3 OCLC 1061216207 von Struve Friedrich Georg Wilhelm July 1857 Comptes rendus hebdomadaires des seances de l Academie des sciences publies par MM les secretaires perpetuels Gallica p 509 Retrieved 30 August 2021 Tipler Paul A Mosca Gene 2004 Physics for Scientists and Engineers 5th ed W H Freeman p 3 ISBN 0716783398 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 realta tra filosofia scienza ed esistenza umana in Italian Armando Editore pp 93 94 101 ISBN 9788883585326 Retrieved 13 October 2015 Rapport sur le choix d une unite de mesure lu a l Academie des sciences le 19 mars 1791 in French Gallica bnf fr 15 October 2007 Retrieved 25 March 2013 Nous proposerons donc de mesurer immediatement un arc du meridien depuis Dunkerque jusqu a Bracelone ce qui comprend un peu plus de neuf degres amp demi We propose then to measure directly an arc of the meridian between Dunkirk and Barcelona this spans a little more than nine and a half degrees p 8 Paolo Agnoli and Giulio D Agostini Why does the meter beat the second December 2004 pp 1 29 Archives Parlementaires sul philologic stanford edu p 379 Retrieved 4 November 2021 Ramani Madhvi How France created the metric system www bbc com Retrieved 21 May 2019 Guedj 2001 Alder 2002 a b c d e Larousse Pierre 1817 1875 1866 1877 Grand dictionnaire universel du XIXe siecle francais historique geographique mythologique bibliographique T 11 MEMO O par M Pierre Larousse p 163 a b Levallois Jean Jacques 1986 La Vie des sciences Gallica in French pp 288 290 269 276 277 283 Retrieved 13 May 2019 Robinson Andrew 10 August 2011 History How Earth shaped up Nature 476 7359 149 150 Bibcode 2011Natur 476 149R doi 10 1038 476149a ISSN 1476 4687 Ferreiro Larrie D 25 June 2013 Measure of the Earth The Enlightenment Expedition That Reshaped Our World Basic Books ISBN 978 0 465 06381 9 Clarke amp Helmert 1911b pp 803 804 a b c This article incorporates text from this source which is in the public domain Ibanez e Ibanez de Ibero Carlos 1881 Discursos leidos ante la Real Academia de Ciencias Exactas Fisicas y Naturales en la recepcion publica de Don Joaquin Barraquer y Rovira PDF Madrid Imprenta de la Viuda e Hijo de D E Aguado pp 70 78 Nomination of the Struve geodetic arc for inscription on the World Heritage List PDF Retrieved 13 May 2019 Hirsch Adolphe 1861 Experiences chronoscopiques sur la vitesse des differentes sensations et de la transmission nerveuse E Periodica in French doi 10 5169 seals 87978 Retrieved 18 April 2021 Debarbat Suzanne Quinn Terry 1 January 2019 Les origines du systeme metrique en France et la Convention du metre de 1875 qui a ouvert la voie au Systeme international d unites et a sa revision de 2018 Comptes Rendus Physique 20 1 2 6 21 Bibcode 2019CRPhy 20 6D doi 10 1016 j crhy 2018 12 002 ISSN 1631 0705 Geophysique in Encyclopedia Universalis Encyclopedia Universalis 1996 pp Vol 10 p 370 ISBN 978 2 85229 290 1 OCLC 36747385 History of IMO World Meteorological Organization 8 December 2015 Retrieved 16 March 2021 Wild Heinrich hls dhs dss ch in German Retrieved 16 March 2021 Heinrich VON WILD 1833 1902 in COMlTE INTERNATIONAL DES POIDS ET MESURES PROCES VERBAUX DES SEANCES DEUXIEME SERIE TOME II SESSION DE 1903 PDF BIPM 1903 a b c d Quinn T J 2012 From artefacts to atoms the BIPM and the search for ultimate measurement standards Oxford pp 91 92 70 72 114 117 144 147 8 ISBN 978 0 19 990991 9 OCLC 861693071 Cajori Florian 1921 Swiss Geodesy and the United States Coast Survey The Scientific Monthly Vol 13 no 2 American Association for the Advancement of Science pp 117 129 Poupard James 1825 Transactions of the American Philosophical Society Vol 2 Philadelphia Abraham Small pp 234 240 252 253 274 278 Cajori Florian 1921 Swiss Geodesy and the United States Coast Survey The Scientific Monthly 13 2 117 129 Bibcode 1921SciMo 13 117C ISSN 0096 3771 Clarke Alexander Ross 1873 XIII Results of the comparisons of the standards of length of England Austria Spain United States Cape of Good Hope and of a second Russian standard made at the Ordnance Survey Office Southampton With a preface and notes on the Greek and Egyptian measures of length by Sir Henry James Philosophical Transactions London vol 163 p 463 doi 10 1098 rstl 1873 0014 a b Bigourdan 1901 pp 8 158 159 176 177 a b Parr Albert C 1 April 2006 A Tale About the First Weights and Measures Intercomparison in the United States in 1832 Journal of Research of the National Institute of Standards and Technology 111 1 31 32 36 doi 10 6028 jres 111 003 PMC 4654608 PMID 27274915 via NIST Viik T 2006 F W BESSEL AND GEODESY Struve Geodetic Arc 2006 International Conference The Struve Arc and Extensions in Space and Time Haparanda and Pajala Sweden 13 15 August 2006 p 10 CiteSeerX 10 1 1 517 9501 Bessel Friedrich Wilhelm 1 December 1841 Uber einen Fehler in der Berechnung der franzosischen Gradmessung und seineh Einfluss auf die Bestimmung der Figur der Erde Von Herrn Geh Rath und Ritter Bessel Astronomische Nachrichten 19 7 97 Bibcode 1841AN 19 97B doi 10 1002 asna 18420190702 ISSN 0004 6337 a b c c a Paris vitesse de la lumiere expositions obspm fr Retrieved 12 October 2021 Wolf M C 1882 Recherches historiques sur les etalons de poids et mesures de l observatoire et les appareils qui ont servi a les construire in French Paris Gauthier Villars pp 20 32 OCLC 16069502 a b Clarke Alexander Ross James Henry 1 January 1867 X Abstract of the results of the comparisons of the standards of length of England France Belgium Prussia Russia India Australia made at the ordnance Survey Office Southampton Philosophical Transactions of the Royal Society of London 157 174 doi 10 1098 rstl 1867 0010 S2CID 109333769 NIST Special Publication U S Government Printing Office 1966 p 529 a b Lebon Ernest 1899 Histoire abregee de l astronomie par Ernest Lebon Paris p 168 Zuerich ETH Bibliothek 1991 La meridienne de Dunkerque a Barcelone et la determiniation du metre 1972 1799 E Periodica in French 377 378 doi 10 5169 seals 234595 Retrieved 12 October 2021 Societe de physique et d histoire naturelle de Geneve Geneve Societe de physique et d histoire naturelle de 1859 Memoires de la Societe de physique et d histoire naturelle de Geneve Vol 15 Geneve Georg etc pp 441 444 Societe de physique et d histoire naturelle de Geneve Geneve Societe de physique et d histoire naturelle de 1861 Memoires de la Societe de physique et d histoire naturelle de Geneve Vol 16 Geneve Georg etc p 196 Metric Act of 1866 US Metric Association usma org Retrieved 15 March 2021 Bericht uber die Verhandlungen der vom 30 September bis 7 October 1867 zu BERLIN abgehaltenen allgemeinen Conferenz der Europaischen Gradmessung PDF in German Berlin Central Bureau der Europaischen Gradmessung 1868 pp 123 134 a b Quinn Terry 2019 Wilhelm Foerster s Role in the Metre Convention of 1875 and in the Early Years of the International Committee for Weights and Measures Annalen der Physik 531 5 2 Bibcode 2019AnP 53100355Q doi 10 1002 andp 201800355 ISSN 1521 3889 S2CID 125240402 Bessel Friedrich Wilhelm 1 April 1840 Uber das preufs Langenmaass und die zu seiner Verbreitung durch Copien ergriffenen Maassregeln Astronomische Nachrichten 17 13 193 Bibcode 1840AN 17 193B doi 10 1002 asna 18400171302 ISSN 0004 6337 Britain Great 1824 The Statutes of the United Kingdom of Great Britain and Ireland a b Guillaume Ed 1 January 1916 Le Systeme Metrique est il en Peril L Astronomie 30 244 245 Bibcode 1916LAstr 30 242G ISSN 0004 6302 Zuerich ETH Bibliothek 1864 Rapport a la commission geodesique suisse sur la conference geodesique internationale de Berlin E Periodica in German doi 10 5169 seals 88011 Retrieved 29 November 2021 Zuerich ETH Bibliothek 1865 Sur les progres des travaux geodesiques en Europe E Periodica in German doi 10 5169 seals 88030 Retrieved 29 November 2021 Clarke amp Helmert 1911b pp 801 813 texte Academie des sciences France Auteur du January 1836 Comptes rendus hebdomadaires des seances de l Academie des sciences publies par MM les secretaires perpetuels Gallica pp 428 433 Retrieved 29 November 2021 a b c Hirsch Adolphe 1891 Don Carlos IBANEZ 1825 1891 PDF Bureau International des Poids et Mesures pp 4 8 Retrieved 22 May 2017 BIPM International Metre Commission www bipm org Retrieved 26 May 2017 a b A Note on the History of the IAG IAG Homepage Retrieved 26 May 2017 Ross Clarke Alexander James Henry 1 January 1873 XIII Results of the comparisons of the standards of length of England Austria Spain United States Cape of Good Hope and of a second Russian standard made at the Ordnance Survey Office Southampton With a preface and notes on the Greek and Egyptian measures of length by Sir Henry James Philosophical Transactions of the Royal Society of London 163 445 469 doi 10 1098 rstl 1873 0014 a b Brunner Jean 1857 Comptes rendus hebdomadaires des seances de l Academie des sciences publies par MM les secretaires perpetuels Gallica in French pp 150 153 Retrieved 15 May 2019 a b c Soler T 1 February 1997 A profile of General Carlos Ibanez e Ibanez de Ibero first president of the International Geodetic Association Journal of Geodesy 71 3 176 188 Bibcode 1997JGeod 71 176S doi 10 1007 s001900050086 ISSN 1432 1394 S2CID 119447198 a b Wolf Charles 1827 1918 Auteur du texte 1882 Recherches historiques sur les etalons de poids et mesures de l Observatoire et les appareils qui ont servi a les construire par M C Wolf in French pp C 38 39 C 2 4 Wolf Rudolf January 1891 Comptes rendus hebdomadaires des seances de l Academie des sciences publies par MM les secretaires perpetuels Gallica pp 370 371 Retrieved 30 August 2021 Brenni Paolo 1996 19th Century French Scientific Instrument Makers XI The Brunners and Paul Gautier PDF Bulletin of the Scientific Instrument Society 49 3 5 via Universidad de Navarra Schiavon Martina 1 December 2006 Les officiers geodesiens du Service geographique de l armee et la mesure de l arc de meridien de Quito 1901 1906 Histoire amp mesure in French XXI XXI 2 55 94 doi 10 4000 histoiremesure 1746 ISSN 0982 1783 a b Experiences faites avec l appareil a mesurer les bases appertant a la commission de la carte d Espagne ouvrage publie par ordre de la reine in French J Dumaine 1860 a b National Institute of Standards and Technology 2003 Historical context of the SI Unit of length meter Perard Albert 1957 Carlos IBANEZ DE IBERO 14 avril 1825 29 janvier 1891 par Albert Perard inauguration d un monument eleve a sa memoire PDF Institut de France Academie des sciences pp 26 28 Dodis Diplomatische Dokumente der Schweiz Documents diplomatiques suisses Documenti diplomatici svizzeri Diplomatic Documents of Switzerland 30 March 1875 Bericht der schweizerischen Delegierten an der internationalen Meterkonferenz an den Bundesprasidenten und Vorsteher des Politischen Departements J J Scherer in French Diplomatische Dokumente der Schweiz Documents diplomatiques suisses Documenti diplomatici svizzeri Diplomatic Documents of Switzerland Dodis retrieved 20 September 2021 BIPM la definition du metre www bipm org Retrieved 15 May 2019 This article incorporates text from this source which is in the public domain Ritter Elie 1858 Manuel theorique et pratique de l application de la methode des moindres carres au calcul des observations in French Mallet Bachelier This article incorporates text from this source which is in the public domain Perrier Georges 1872 1946 Auteur du texte 1933 Cours de geodesie et d astronomie par G Perrier in French pp 17 18 This article incorporates text from this source which is in the public domain The Nobel Prize in Physics 1920 NobelPrize org Retrieved 13 March 2021 This article incorporates text from this source which is in the public domain Report from Charles S Peirce on his second European trip for the Anual Report of the Superintendent of the U S Coast Survey New York 18 05 1877 www unav es Retrieved 22 May 2019 Faye Herve 1880 Comptes rendus hebdomadaires des seances de l Academie des sciences publies par MM les secretaires perpetuels Gallica in French pp 1463 1466 Retrieved 22 May 2019 Torge Wolfgang 2016 Rizos Chris Willis Pascal eds From a Regional Project to an International Organization The Baeyer Helmert Era of the International Association of Geodesy 1862 1916 IAG 150 Years International Association of Geodesy Symposia Springer International Publishing 143 3 18 doi 10 1007 1345 2015 42 ISBN 9783319308951 Torge W 1 April 2005 The International Association of Geodesy 1862 to 1922 from a regional project to an international organization Journal of Geodesy 78 9 558 568 Bibcode 2005JGeod 78 558T doi 10 1007 s00190 004 0423 0 ISSN 1432 1394 S2CID 120943411 Archived at Ghostarchive and the Wayback Machine Laboratoire national de metrologie et d essais 13 June 2018 Le metre l aventure continue retrieved 16 May 2019 a b c d Histoire du metre Direction Generale des Entreprises DGE in French Retrieved 16 May 2019 Maxwell James Clerk 1873 A Treatise On Electricity and Magnetism Vol 1 London MacMillan and Co p 3 Marion Jerry B 1982 Physics For Science and Engineering CBS College Publishing p 3 ISBN 978 4 8337 0098 6 a b 17th General Conference on Weights and Measures 1983 Resolution 1 Retrieved 7 December 2022 BIPM 20 May 2019 Mise en pratique for the definition of the meter in the SI BIPM The exact value is 299792 458 m s 1079 252 848 4 5 km h a b c Iodine l 633 nm PDF 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 Edlen 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 978 0 12 475977 0 The error introduced by using air 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 113 114 a b Zagar 1999 pp 6 65ff Bigourdan1901 pp 20 21 CGPM Compte rendus de la 1ere reunion 1889 PDF BIPM CGPM Comptes rendus de le 7e reunion 1927 PDF p 49 Judson 1976 Taylor and Thompson 2008a Appendix 1 p 70 Meter is Redefined US National Geographic Society Retrieved 22 October 2019 Taylor and Thompson 2008a Appendix 1 p 77 Cardarelli 2003 Definition of the metre Resolution 1 of the 17th meeting of the CGPM 1983 Metrisches System hls dhs dss ch in German Retrieved 15 December 2021 Kartografie hls dhs dss ch in German Retrieved 13 December 2021 Dufour G H 1861 Notice sur la carte de la Suisse dressee par l Etat Major Federal Le Globe Revue genevoise de geographie 2 1 5 22 doi 10 3406 globe 1861 7582 Durand Roger 1991 Guillaume Henri Dufour dans son Temps 1787 1875 in French Librairie Droz p 145 ISBN 978 2 600 05069 2 Napoleon III hls dhs dss ch in German Retrieved 14 December 2021 Henri Dufour et la carte de la Suisse Musee national Blog sur l histoire suisse in French 14 July 2019 Retrieved 15 December 2021 Yates James 1856 Narrative of the Origin and Formation of the International Association for Obtaining a Uniform Decimal System of Measures Weights and Coins Bell and Daldy pp 2 6 Brenni Paolo 1996 19th Century French Scientific Instrument Makers XI The Brunners and Paul Gautier PDF Bulletin of the Scientific Instrument Society 49 3 5 via UNAV Appell Paul 1925 Le centenaire du general Ibanez de Ibero Revue internationale de l enseignement 79 1 208 211 a b texte Ismaʿil Afandi Muṣṭafa 1825 1901 Auteur du 1864 Recherche des coefficients de dilatation et etalonnage de l appareil a mesurer les bases geodesiques appartenant au gouvernement egyptien par Ismail Effendi Moustapha Tardi Pierre 1897 1972 Auteur du texte 1934 Traite de geodesie par le capitaine P Tardi preface par le general G Perrier p 25 Zuerich ETH Bibliothek Proces verbaux des seances de la commission geodesique suisse E Periodica in German pp 14 18 Retrieved 18 December 2021 Boucheron Patrick Delalande Nicolas Mazel Florian Potin Yann Singaravelou Pierre 2018 Histoire mondiale de la France Edition augmentee de quinze notices inedites ed Paris p 694 ISBN 978 2 7578 7442 4 OCLC 1057452808 a b Metrisches System hls dhs dss ch in German Retrieved 9 December 2021 Taylor amp Thompson 2003 p 11 Astin amp Karo 1959 Arnold Dieter 1991 Building in Egypt pharaonic stone masonry Oxford Oxford University Press ISBN 978 0 19 506350 9 p 251 Dictionary of the Scots Language Archived from the original on 21 March 2012 Retrieved 6 August 2011 The Penny Magazine of the Society for the Diffusion of Useful Knowledge Charles Knight 6 June 1840 pp 221 22 Hallock William Wade Herbert T 1906 Outlines of the evolution of weights and measures and the metric system London The Macmillan Company pp 66 69 Cardarelli 2004 Hofstad Knut Mil Store norske leksikon Retrieved 18 October 2019 References EditAlder Ken 2002 The Measure of All Things The Seven Year Odyssey and Hidden Error That Transformed the World New York Free Press ISBN 978 0 7432 1675 3 Astin A V amp Karo H Arnold 1959 Refinement of values for the yard and the pound Washington DC National Bureau of Standards republished on National Geodetic Survey web site and the Federal Register Doc 59 5442 Filed 30 June 1959 Judson Lewis V 1 October 1976 1963 Barbrow Louis E ed Weights and Measures Standards of the United States a brief history 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 Bigourdan Guillaume 1901 Le systeme metrique des poids et mesures son etablissement et sa propagation graduelle avec l histoire des operations qui ont servi a determiner le metre et le kilogramme The metric system of weights and measures its establishment and gradual propagation with the history of the operations which served to determine the meter and the kilogram Paris Gauthier Villars Clarke Alexander Ross Helmert Friedrich Robert 1911b Earth Figure of the In Chisholm Hugh ed Encyclopaedia Britannica Vol 8 11th ed Cambridge University Press pp 801 813 Guedj Denis 2001 La Mesure du Monde The Measure of the World Translated by Goldhammer Art Chicago University of Chicago Press Cardarelli Francois 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 978 1 85233 682 0 Retrieved 26 January 2017 Data from Giacomo P Du platine a la lumiere From platinum to light Bull Bur Nat Metrologie 102 1995 5 14 Cardarelli F 2004 Encyclopaedia of Scientific Units Weights and Measures Their SI Equivalences and Origins 2nd ed Springer pp 120 124 ISBN 1 85233 682 X 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 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 Systeme International d Unites 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 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 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 Retrieved from https en wikipedia org w index php title Metre amp oldid 1134110341, wikipedia, wiki, book, books, library,

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