PhotosLocation

From Wikipedia, the free encyclopedia
(Redirected from History of prime meridians)

A prime meridian is an arbitrarily-chosen meridian (a line of longitude) in a geographic coordinate system at which longitude is defined to be 0°. Together, a prime meridian and its anti-meridian (the 180th meridian in a 360°-system) form a great circle. This great circle divides a spheroid, like Earth, into two hemispheres: the Eastern Hemisphere and the Western Hemisphere (for an east-west notational system). For Earth's prime meridian, various conventions have been used or advocated in different regions throughout history. [1] Earth's current international standard prime meridian is the IERS Reference Meridian. It is derived, but differs slightly, from the Greenwich Meridian, the previous standard. [2]

Gerardus Mercator in his Atlas Cosmographicae (1595) used a prime meridian somewhere close to 25°W, passing just to the west of Santa Maria Island in the Azores in the Atlantic Ocean. His 180th meridian runs along the Strait of Anián (Bering Strait)

A prime meridian for a planetary body not tidally locked (or at least not in synchronous rotation) is entirely arbitrary, unlike an equator, which is determined by the axis of rotation. However, for celestial objects that are tidally locked (more specifically, synchronous), their prime meridians are determined by the face always inward of the orbit (a planet facing its star, or a moon facing its planet), just as equators are determined by rotation.

Longitudes for the Earth and Moon are measured from their prime meridian (at 0°) to 180° east and west. For all other Solar System bodies, longitude is measured from 0° (their prime meridian) to 360°. West longitudes are used if the rotation of the body is prograde (or 'direct', like Earth), meaning that its direction of rotation is the same as that of its orbit. East longitudes are used if the rotation is retrograde. [3]

History

Ptolemy's 1st projection, redrawn under Maximus Planudes around 1300, using a prime meridian through the Canary Islands west of Africa, at the left-hand edge of the map. (The obvious central line shown here is the junction of two sheets).

The notion of longitude for Greeks was developed by the Greek Eratosthenes (c. 276 – 195 BCE) in Alexandria, and Hipparchus (c. 190 – 120 BCE) in Rhodes, and applied to a large number of cities by the geographer Strabo (64/63 BCE – c. 24 CE). But it was Ptolemy (c. 90 – 168 CE) who first used a consistent meridian for a world map in his Geographia.

Ptolemy used as his basis the " Fortunate Isles", a group of islands in the Atlantic, which are usually associated with the Canary Islands (13° to 18°W), although his maps correspond more closely to the Cape Verde islands (22° to 25° W). The main point is to be comfortably west of the western tip of Africa (17.5° W) as negative numbers were not yet in use. His prime meridian corresponds to 18° 40' west of Winchester (about 20°W) today. [1] At that time the chief method of determining longitude was by using the reported times of lunar eclipses in different countries.

One of the earliest known descriptions of standard time in India appeared in the 4th century CE astronomical treatise Surya Siddhanta. Postulating a spherical Earth, the book described the thousands years old customs of the prime meridian, or zero longitude, as passing through Avanti, the ancient name for the historic city of Ujjain, and Rohitaka, the ancient name for Rohtak ( 28°54′N 76°38′E / 28.900°N 76.633°E / 28.900; 76.633 (Rohitaka (Rohtak))), a city near the Kurukshetra. [4][ better source needed]

William Grigg's facsimile of the 1529 Spanish Padron Real, from the copy made by Diogo Ribeiro and held by the Vatican Library.

Ptolemy's Geographia was first printed with maps at Bologna in 1477, and many early globes in the 16th century followed his lead. But there was still a hope that a "natural" basis for a prime meridian existed. Christopher Columbus reported (1493) that the compass pointed due north somewhere in mid-Atlantic, and this fact was used in the important Treaty of Tordesillas of 1494, which settled the territorial dispute between Spain and Portugal over newly discovered lands. The Tordesillas line was eventually settled at 370 leagues (2,193 kilometers, 1,362 statute miles, or 1,184 nautical miles) west of Cape Verde. [a] This is shown in the copies of Spain's Padron Real made by Diogo Ribeiro in 1527 and 1529. São Miguel Island (25.5°W) in the Azores was still used for the same reason as late as 1594 by Christopher Saxton, although by then it had been shown that the zero magnetic declination line did not follow a line of longitude. [8]

1571 Africa map by Abraham Ortelius, with Cape Verde as its prime meridian.
1682 map of East Asia by Giacomo Cantelli, with Cape Verde as its prime meridian; Japan is thus located around 180° E.

In 1541, Mercator produced his famous 41 cm terrestrial globe and drew his prime meridian precisely through Fuerteventura (14°1'W) in the Canaries. His later maps used the Azores, following the magnetic hypothesis. But by the time that Ortelius produced the first modern atlas in 1570, other islands such as Cape Verde were coming into use. In his atlas longitudes were counted from 0° to 360°, not 180°W to 180°E as is usual today. This practice was followed by navigators well into the 18th century. [9] In 1634, Cardinal Richelieu used the westernmost island of the Canaries, El Hierro, 19° 55' west of Paris, as the choice of meridian. The geographer Delisle decided to round this off to 20°, so that it simply became the meridian of Paris disguised. [10]

In the early 18th century the battle was on to improve the determination of longitude at sea, leading to the development of the marine chronometer by John Harrison. But it was the development of accurate star charts, principally by the first British Astronomer Royal, John Flamsteed between 1680 and 1719 and disseminated by his successor Edmund Halley, that enabled navigators to use the lunar method of determining longitude more accurately using the octant developed by Thomas Godfrey and John Hadley. [11]

In the 18th century most countries in Europe adapted their own prime meridian, usually through their capital, hence in France the Paris meridian was prime, in Prussia it was the Berlin meridian, in Denmark the Copenhagen meridian, and in United Kingdom the Greenwich meridian.

Between 1765 and 1811, Nevil Maskelyne published 49 issues of the Nautical Almanac based on the meridian of the Royal Observatory, Greenwich. "Maskelyne's tables not only made the lunar method practicable, they also made the Greenwich meridian the universal reference point. Even the French translations of the Nautical Almanac retained Maskelyne's calculations from Greenwich – in spite of the fact that every other table in the Connaissance des Temps considered the Paris meridian as the prime." [12]

In 1884, at the International Meridian Conference in Washington, D.C., 22 countries voted to adopt the Greenwich meridian as the prime meridian of the world. [13] The French argued for a neutral line, mentioning the Azores and the Bering Strait, but eventually abstained and continued to use the Paris meridian until 1911.

The current international standard Prime Meridian is the IERS Reference Meridian. The International Hydrographic Organization adopted an early version of the IRM in 1983 for all nautical charts. [14] It was adopted for air navigation by the International Civil Aviation Organization on 3 March 1989. [15]

International prime meridian

Since 1984, the international standard for the Earth's prime meridian is the IERS Reference Meridian. Between 1884 and 1984, the meridian of Greenwich was the world standard. These meridians are physically very close to each other.

Prime meridian at Greenwich

The line of the Greenwich meridian at the Royal Observatory, Greenwich

In October 1884 the Greenwich Meridian was selected by delegates (forty-one delegates representing twenty-five nations) to the International Meridian Conference held in Washington, D.C., United States to be the common zero of longitude and standard of time reckoning throughout the world. [16] [b]

The position of the historic prime meridian, based at the Royal Observatory, Greenwich, was established by Sir George Airy in 1851. It was defined by the location of the Airy Transit Circle ever since the first observation he took with it. [18] Prior to that, it was defined by a succession of earlier transit instruments, the first of which was acquired by the second Astronomer Royal, Edmond Halley in 1721. It was set up in the extreme north-west corner of the Observatory between Flamsteed House and the Western Summer House. This spot, now subsumed into Flamsteed House, is roughly 43 metres to the west of the Airy Transit Circle, a distance equivalent to roughly 2 seconds of longitude. [19] It was Airy's transit circle that was adopted in principle (with French delegates, who pressed for adoption of the Paris meridian abstaining) as the Prime Meridian of the world at the 1884 International Meridian Conference. [20] [21]

All of these Greenwich meridians were located via an astronomic observation from the surface of the Earth, oriented via a plumb line along the direction of gravity at the surface. This astronomic Greenwich meridian was disseminated around the world, first via the lunar distance method, then by chronometers carried on ships, then via telegraph lines carried by submarine communications cables, then via radio time signals. One remote longitude ultimately based on the Greenwich meridian using these methods was that of the North American Datum 1927 or NAD27, an ellipsoid whose surface best matches mean sea level under the United States.

IERS Reference Meridian

Beginning in 1973 the International Time Bureau and later the International Earth Rotation and Reference Systems Service changed from reliance on optical instruments like the Airy Transit Circle to techniques such as lunar laser ranging, satellite laser ranging, and very-long-baseline interferometry. The new techniques resulted in the IERS Reference Meridian, the plane of which passes through the centre of mass of the Earth. This differs from the plane established by the Airy transit, which is affected by vertical deflection (the local vertical is affected by influences such as nearby mountains). The change from relying on the local vertical to using a meridian based on the centre of the Earth caused the modern prime meridian to be 5.3″ east of the astronomic Greenwich prime meridian through the Airy Transit Circle. At the latitude of Greenwich, this amounts to 102 metres. [22] This was officially accepted by the Bureau International de l'Heure (BIH) in 1984 via its BTS84 (BIH Terrestrial System) that later became WGS84 (World Geodetic System 1984) and the various International Terrestrial Reference Frames (ITRFs).

Due to the movement of Earth's tectonic plates, the line of 0° longitude along the surface of the Earth has slowly moved toward the west from this shifted position by a few centimetres; that is, towards the Airy Transit Circle (or the Airy Transit Circle has moved toward the east, depending on your point of view) since 1984 (or the 1960s). With the introduction of satellite technology, it became possible to create a more accurate and detailed global map. With these advances there also arose the necessity to define a reference meridian that, whilst being derived from the Airy Transit Circle, would also take into account the effects of plate movement and variations in the way that the Earth was spinning. [23] As a result, the IERS Reference Meridian was established and is commonly used to denote the Earth's prime meridian (0° longitude) by the International Earth Rotation and Reference Systems Service, which defines and maintains the link between longitude and time. Based on observations to satellites and celestial compact radio sources (quasars) from various coordinated stations around the globe, Airy's transit circle drifts northeast about 2.5 centimetres per year relative to this Earth-centred 0° longitude.

It is also the reference meridian of the Global Positioning System operated by the United States Department of Defense, and of WGS84 and its two formal versions, the ideal International Terrestrial Reference System (ITRS) and its realization, the International Terrestrial Reference Frame (ITRF). [24] [25] [c] A current convention on the Earth uses the line of longitude 180° opposite the IRM as the basis for the International Date Line.

List of places

On Earth, starting at the North Pole and heading south to the South Pole, the IERS Reference Meridian (as of 2016) passes through:

Co-ordinates
(approximate)
Country, territory or sea Notes
90°0′N 0°0′E / 90.000°N 0.000°E / 90.000; 0.000 (North Pole) Arctic Ocean
85°46′N 0°0′E / 85.767°N 0.000°E / 85.767; 0.000 (EEZ of Greenland (Denmark)) Exclusive Economic Zone (EEZ) of Greenland ( Denmark)
81°39′N 0°0′E / 81.650°N 0.000°E / 81.650; 0.000 (Greenland Sea) Greenland Sea
80°29′N 0°0′E / 80.483°N 0.000°E / 80.483; 0.000 (EEZ of Svalbard (Norway)) EEZ of Svalbard ( Norway)
76°11′N 0°0′E / 76.183°N 0.000°E / 76.183; 0.000 (International waters) International waters
73°44′N 0°0′E / 73.733°N 0.000°E / 73.733; 0.000 (EEZ of Jan Mayen) EEZ of Jan Mayen ( Norway)
72°53′N 0°0′E / 72.883°N 0.000°E / 72.883; 0.000 (Norwegian Sea) Norwegian Sea
69°7′N 0°0′E / 69.117°N 0.000°E / 69.117; 0.000 (International waters) International waters
64°42′N 0°0′E / 64.700°N 0.000°E / 64.700; 0.000 (EEZ of Norway) EEZ of Norway
63°29′N 0°0′E / 63.483°N 0.000°E / 63.483; 0.000 (EEZ of Great Britain) EEZ of Great Britain
61°0′N 0°0′E / 61.000°N 0.000°E / 61.000; 0.000 (North Sea) North Sea
53°46′N 0°0′E / 53.767°N 0.000°E / 53.767; 0.000 (United Kingdom)   United Kingdom From Tunstall in East Riding to Peacehaven, passing through Greenwich
50°47′N 0°0′E / 50.783°N 0.000°E / 50.783; 0.000 (English Channel) English Channel EEZ of Great Britain
50°14′N 0°0′E / 50.233°N 0.000°E / 50.233; 0.000 (EEZ of France) English Channel EEZ of France
49°20′N 0°0′E / 49.333°N 0.000°E / 49.333; 0.000 (France)   France From Villers-sur-Mer to Gavarnie
42°41′N 0°0′E / 42.683°N 0.000°E / 42.683; 0.000 (Spain)   Spain From Cilindro de Marboré to Castellón de la Plana
39°56′N 0°0′E / 39.933°N 0.000°E / 39.933; 0.000 (Mediterranean Sea) Mediterranean Sea Gulf of Valencia; EEZ of Spain
38°52′N 0°0′E / 38.867°N 0.000°E / 38.867; 0.000 (Spain)   Spain From El Verger to Calp
38°38′N 0°0′E / 38.633°N 0.000°E / 38.633; 0.000 (Mediterranean Sea) Mediterranean Sea EEZ of Spain
37°1′N 0°0′E / 37.017°N 0.000°E / 37.017; 0.000 (EEZ of Algeria) Mediterranean Sea EEZ of Algeria
35°50′N 0°0′E / 35.833°N 0.000°E / 35.833; 0.000 (Algeria)   Algeria From Stidia to Algeria-Mali border near Bordj Badji Mokhtar
21°52′N 0°0′E / 21.867°N 0.000°E / 21.867; 0.000 (Mali)   Mali Passing through Gao
15°00′N 0°0′E / 15.000°N 0.000°E / 15.000; 0.000 (Burkina Faso)   Burkina Faso For about 432 km, running through Cinkassé.
11°7′N 0°0′E / 11.117°N 0.000°E / 11.117; 0.000 (Togo)   Togo For about 3.4 km
11°6′N 0°0′E / 11.100°N 0.000°E / 11.100; 0.000 (Ghana)   Ghana For about 16 km
10°58′N 0°0′E / 10.967°N 0.000°E / 10.967; 0.000 (Togo)   Togo For about 39 km
10°37′N 0°0′E / 10.617°N 0.000°E / 10.617; 0.000 (Ghana)   Ghana From the Togo-Ghana border near Bunkpurugu to Tema
Passing through Lake Volta at 7°46′N 0°0′E / 7.767°N 0.000°E / 7.767; 0.000 (Lake Volta)
5°37′N 0°0′E / 5.617°N 0.000°E / 5.617; 0.000 (EEZ of Ghana in Atlantic Ocean) Atlantic Ocean EEZ of Ghana
1°58′N 0°0′E / 1.967°N 0.000°E / 1.967; 0.000 (International waters) International waters
0°0′N 0°0′E / 0.000°N 0.000°E / 0.000; 0.000 (Equator) Passing through the Equator (see Null Island)
51°43′S 0°0′E / 51.717°S 0.000°E / -51.717; 0.000 (EEZ of Bouvet Island) EEZ of Bouvet Island ( Norway)
57°13′S 0°0′E / 57.217°S 0.000°E / -57.217; 0.000 (International waters) International waters
60°0′S 0°0′E / 60.000°S 0.000°E / -60.000; 0.000 (Southern Ocean) Southern Ocean International waters
69°36′S 0°0′E / 69.600°S 0.000°E / -69.600; 0.000 (Antarctica) Antarctica Queen Maud Land, claimed by   Norway
90°0′S 0°0′E / 90.000°S 0.000°E / -90.000; 0.000 (Amundsen–Scott South Pole Station) Antarctica Amundsen–Scott South Pole Station, South Pole

Prime meridian on other celestial bodies

As on the Earth, prime meridians must be arbitrarily defined. Often a landmark such as a crater is used; other times a prime meridian is defined by reference to another celestial object, or by magnetic fields. The prime meridians of the following planetographic systems have been defined:

  • Two different heliographic coordinate systems are used on the Sun. The first is the Carrington heliographic coordinate system. In this system, the prime meridian passes through the center of the solar disk as seen from the Earth on 9 November 1853, which is when the English astronomer Richard Christopher Carrington started his observations of sunspots. [26] The second is the Stonyhurst heliographic coordinates system, originated at Stonyhurst Observatory in Lancashire, England.
  • In 1975 the prime meridian of Mercury was defined [27] [28] to be 20° east of the crater Hun Kal. [29] This meridian was chosen because it runs through the point on Mercury's equator where the average temperature is highest (due to the planet's rotation and orbit, the sun briefly retrogrades at noon at this point during perihelion, giving it more sunlight). [30] [31] [32]
  • Defined [33] in 1992, the prime meridian of Venus passes through the central peak in the crater Ariadne, chosen arbitrarily. [34]
  • The prime meridian of the Moon lies directly in the middle of the face of the Moon visible from Earth and passes near the crater Bruce.
  • The prime meridian of Mars was established in 1971 [35] and passes through the center of the crater Airy-0, although it is fixed by the longitude of the Viking 1 lander, which is defined to be 47.95137°W. [36]
  • The prime meridian on Ceres runs through the Kait crater, which was arbitrarily chosen because it is near the equator (about 2° south). [37]
  • The prime meridian on 4 Vesta is 4 degrees east of the crater Claudia, chosen because it is sharply defined. [38]
  • Jupiter has several coordinate systems because its cloud tops—the only part of the planet visible from space—rotate at different rates depending on latitude. [39] It is unknown whether Jupiter has any internal solid surface that would enable a more Earth-like coordinate system. System I and System II coordinates are based on atmospheric rotation, and System III coordinates use Jupiter's magnetic field. The prime meridians of Jupiter's four Galilean moons were established in 1979. [40]
    • Europa's prime meridian is defined such that the crater Cilix is at 182° W. The 0° longitude runs through the middle of the face that is always turned towards Jupiter.
    • Io's prime meridian, like that of Earth's moon, is defined so that it runs through the middle of the face that is always turned towards Jupiter (the near side, known as the subjovian hemisphere). [41]
    • Ganymede's prime meridian is defined such that the crater Anat is at 128° W, and the 0° longitude runs through the middle of the subjovian hemisphere. [42]
    • Callisto's prime meridian is defined such that the crater Saga is at 326° W. [43]
  • Titan is the largest moon of Saturn and, like the Earth's moon, always has the same face towards Saturn, and so the middle of that face is 0 longitude.
  • Like Jupiter, Neptune is a gas giant, so any surface is obscured by clouds. The prime meridian of its largest moon, Triton, was established in 1991. [44]
  • Pluto's prime meridian is defined as the meridian passing through the center of the face that is always towards Charon, its largest moon, as the two are tidally locked to each other. Charon's prime meridian is similarly defined as the meridian always facing directly toward Pluto.

List of historic prime meridians on Earth

Locality Modern longitude Meridian name Image Comment
Bering Strait 168°30 W
Line across the Earth
168°
168th meridian west
Offered in 1884 as possibility for a neutral prime meridian by Pierre Janssen at the International Meridian Conference [45]
Washington, D.C. 77°0356.07″ W (1897) or 77°0402.24″ W (NAD 27)[ clarification needed] or 77°0401.16″ W (NAD 83) New Naval Observatory meridian
Line across the Earth
77°
77th meridian west
77°0248.0″ W, 77°0302.3″, 77°0306.119″ W or 77°0306.276″ W (both presumably NAD 27). If NAD27, the latter would be 77°0305.194″ W (NAD 83) Old Naval Observatory meridian
77°0211.56299″ W (NAD 83), [46] 77°0211.55811″ W (NAD 83), [47] 77°0211.58325″ W (NAD 83) [48] (three different monuments originally intended to be on the White House meridian) White House meridian
77°0032.6″ W (NAD 83) Capitol meridian
Philadelphia 75° 10 12″ W
Line across the Earth
75°
75th meridian west
[49] [50]
Rio de Janeiro 43° 10 19″ W
Line across the Earth
43°
43rd meridian west
[51]
Fortunate Isles / Azores 25° 40 32″ W
Line across the Earth
25°
25th meridian west
Used until the Middle Ages, proposed as one possible neutral meridian by Pierre Janssen at the International Meridian Conference [52]
El Hierro (Ferro),
Canary Islands
18° 03 W,
later redefined as
17° 39 46″ W
Ferro meridian
Line across the Earth
18°
18th meridian west
[53]
Tenerife 16°3822″ W Tenerife meridian
Line across the Earth
16°
16th meridian west
Rose to prominence with Dutch cartographers and navigators after they abandoned the idea of a magnetic meridian [54]
Lisbon 9° 07 54.862″ W
Line across the Earth
9th meridian west
[55]
Cadiz 6° 17 35.4" W Cadiz meridian
Line across the Earth
6th meridian west
Royal Observatory in southeast tower of Castillo de la Villa, used 1735–1850 by Spanish Navy. [56] [57]
Madrid 3° 41 16.58″ W
Line across the Earth
3rd meridian west
[55]
Kew 0° 00 19.0″ W Prime Meridian (prior to Greenwich)
Line across the Earth
Prime meridian
Located at King George III's Kew Observatory
Greenwich 0° 00 05.33″ W United Kingdom Ordnance Survey Zero Meridian Bradley Meridian [19]
0° 00 05.3101″ W Greenwich meridian Airy Meridian [19]
0° 00 00.00″ IERS Reference Meridian
Paris 2° 20 14.025″ E Paris meridian
Line across the Earth
2nd meridian east
Brussels 4° 22 4.71″ E
Line across the Earth
4th meridian east
[55]
Antwerp 4° 24 E Antwerp meridian
Amsterdam 4° 53 E Through the Westerkerk in Amsterdam; used to define the legal time in the Netherlands from 1909 to 1937 [58]
Pisa 10° 24 E
Line across the Earth
10°
10th meridian east
[49]
Oslo (Kristiania) 10° 43 22.5″ E [49] [50]
Florence 11°15 E Florence meridian
Line across the Earth
11°
11th meridian east
Used in the Peters projection, 180° from a meridian running through the Bering Strait
Rome 12° 27 08.4″ E Meridian of Monte Mario
Line across the Earth
12°
12th meridian east
Used in Roma 40 Datum [59]
Copenhagen 12° 34 32.25″ E Rundetårn [60]
Naples 14° 15 E
Line across the Earth
14°
14th meridian east
[52]
Pressburg 17° 06 03″ E Meridianus Posoniensis
Line across the Earth
17°
17th meridian east
Used by Sámuel Mikoviny
Stockholm 18° 03 29.8″ E
Line across the Earth
18°
18th meridian east
At the Stockholm Observatory [55]
Buda 19° 03 37″ E Meridianu(s) Budense
Line across the Earth
19°
19th meridian east
Used between 1469 and 1495; introduced by Regiomontanus, used by Marcin Bylica, Galeotto Marzio, Miklós Erdélyi (1423–1473), Johannes Tolhopff (c. 1445–1503), Johannes Muntz. Set in the royal castle (and observatory) of Buda. [d]
Kraków 19° 57 21.43″ E Kraków meridian at the Old Kraków Observatory at the Śniadecki' College; mentioned also in Nicolaus Copernicus's work On the Revolutions of the Heavenly Spheres.
Warsaw 21° 00 42″ E Warsaw meridian
Line across the Earth
21°
21st meridian east
[55]
Várad 21° 55 16″ E Tabulae Varadienses
Line across the Earth
21°
21st meridian east
[64] Between 1464 and 1667, a prime meridian was set in the Fortress of Oradea (Varadinum at the time) by Georg von Peuerbach. [65] In his logbook Columbus stated, he had one copy of Tabulae Varadienses (Tabula Varadiensis or Tabulae directionum) on board to calculate the actual meridian based on the position of the Moon, in correlation to Várad. Amerigo Vespucci also recalled, how was he acquired the knowledge to calculate meridians by means of these tables. [66]
Alexandria 29° 53 E Meridian of Alexandria
Line across the Earth
29°
29th meridian east
The meridian of Ptolemy's Almagest.
Saint Petersburg 30° 19 42.09″ E Pulkovo meridian
Line across the Earth
30°
30th meridian east
Great Pyramid of Giza 31° 08 03.69″ E
Line across the Earth
31°
31st meridian east
1884 [67]
Jerusalem 35° 13 47.1″ E
Line across the Earth
35°
35th meridian east
[50]
Mecca 39° 49 34″ E
Line across the Earth
39°
39th meridian east
See also Mecca Time
Approx. 59° E
Line across the Earth
59°
59th meridian east
Maimonides [68] calls this point אמצע היישוב, "the middle of the habitation", i.e. the habitable hemisphere. Evidently this was a convention accepted by Arab geographers of his day.
Ujjain 75° 47 E
Line across the Earth
75°
75th meridian east
Used from 4th century CE Indian astronomy and calendars(see also Time in India). [69]
Kyoto 136° 14 E
Line across the Earth
136°
136th meridian east
Used in 18th and 19th (officially 1779–1871) century Japanese maps. Exact place unknown, but in "Kairekisyo" in Nishigekkoutyou-town in Kyoto, then the capital.[ citation needed]
~ 180
Line across the Earth
180°
180th meridian
Opposite of Greenwich, proposed 13 October 1884 on the International Meridian Conference by Sandford Fleming [52]

See also

Notes

  1. ^ These figures use the legua náutica (nautical league) of four Roman miles totalling 5.926 km (3.682 mi), which was used by Spain during the 15th, 16th, and 17th centuries for navigation. [5] In 1897 Henry Harrise noted that Jaime Ferrer, the expert consulted by King Ferdinand and Queen Isabella, stated that a league was four miles of six stades each. [6] Modern scholars agree that the geographic stade was the Roman or Italian stade, not any of several other Greek stades, supporting these figures. [7] Harrise is in the minority when he uses the stade of 192.27 m (630.8 ft) marked within the stadium at Olympia, Greece, resulting in a league (32 stades) of 6.153 km (3.823 mi), 3.8% larger.
  2. ^ Voting took place on 13 October and the resolutions were adopted on 22 October 1884. [17] The modern prime meridian, the IERS Reference Meridian, is placed very near this meridian. [13]
  3. ^ The astronomic latitude of the Royal Observatory is 51°2838″N whereas its latitude on the European Terrestrial Reference Frame (1989) datum is 51°2840.1247″N.
  4. ^ When Tolhopff handed over his book, titled Stellarium (1480), [61] to King Matthias Corvinus, he emphasized that he had used the meridian of Buda for his calculations. The German physician, Johannes Müntz used it the same way in his 1495 calendar. However, in the second edition, he used the Vienna meridian. [62] [63]

References

  1. ^ a b Norgate & Norgate 2006.
  2. ^ "What is the Prime Meridian and why is it in Greenwich?". Royal Museums Greeenwich. Archived from the original on 13 December 2021. Retrieved 13 December 2021. The IRM is the only meridian that may now be described as the prime meridian of the world, as it defines 0° longitude by international agreement. The IRM passes 102.5 metres to the east of the historic Prime Meridian of the World at the latitude of the Airy Transit Circle here. The entire Observatory and the historic Prime Meridian now lie to the west of the true prime meridian.
  3. ^ Archimal, B. A. (2015), Report of the IAU Working Group on Cartographic Coordinates and Rotational Elements: 2015 (PDF), p. 27 of 46, archived (PDF) from the original on 6 August 2019, retrieved 6 August 2019, The range of longitudes shall extend from 0° to 360°. Thus, west longitudes are used when the rotation is direct, and east longitudes are used when the rotation is retrograde. ... The Earth, Sun, and Moon do not traditionally follow this definition. Their rotations are direct and longitudes run both east and west 180°, or positive to the east 360°.
  4. ^ Schmidt, Olaf H. (1944). "The Computation of the Length of Daylight in Hindu Astronomy". Isis. 35 (3). The University of Chicago Press: 205–211. doi: 10.1086/358709. JSTOR  330729. S2CID  145178197. Archived from the original on 26 January 2022.
  5. ^ Chardon, Roland (1980). "The linear league in North America". Annals of the Association of American Geographers. 70 (2): 129–153 [pp. 142, 144, 151]. doi: 10.1111/j.1467-8306.1980.tb01304.x. JSTOR  2562946.
  6. ^ Harrisse, Henry (1897). The Diplomatic History of America: Its first chapter 1452—1493—1494. London: Stevens. pp. 85–97, 176–190. ISBN  9780697000071. OCLC  1101220811.
  7. ^ Engels, Donald (1985). "The length of Eratosthenes' stade". American Journal of Philology. 106 (3): 298–311. doi: 10.2307/295030. JSTOR  295030.
  8. ^ Hooker 2006.
  9. ^ e.g. Jacob Roggeveen in 1722 reported the longitude of Easter Island as 268° 45' (starting from Fuerteventura) in the Extract from the Official log of Jacob Roggeveen reproduced in Bolton Glanville Corney, ed. (1908), The voyage of Don Felipe Gonzalez to Easter Island in 1770-1, Hakluyt Society, p. 3, retrieved 13 January 2013
  10. ^ Speech by Pierre Janssen, director of the Paris observatory, at the first session of the Meridian Conference. Archived 18 December 2021 at the Wayback Machine
  11. ^ Sobel & Andrewes 1998, pp. 110–115.
  12. ^ Sobel & Andrewes 1998, pp. 197–199.
  13. ^ a b "What is the Prime Meridian - and why is it in Greenwich? | Who decided that the Prime Meridian should be in Greenwich?". Royal Museums Greenwich. n.d. Archived from the original on 5 January 2022. Retrieved 28 December 2021.
  14. ^ "A manual on the technical aspects of the United Nations Convention on the Law of the Sea – 1982" (PDF). Archived (PDF) from the original on 10 September 2008. Retrieved 23 July 2008. (4.89 MB) Section 2.4.4.
  15. ^ WGS 84 Implementation Manual Archived 3 October 2008 at the Wayback Machine page i, 1998
  16. ^ International Conference Held at Washington for the Purpose of Fixing a Prime Meridian and a Universal Day. October, 1884. Protocols of the proceedings. Project Gutenberg. 1884. Archived from the original on 18 December 2021. Retrieved 30 November 2012.
  17. ^ Howse 1997, pp. 12, 137
  18. ^ Forbes, Eric Gray (1975). Greenwich Observatory ... the story of Britain's oldest scientific institution, the Royal Observatory at Greenwich and Herstmonceux, 1675–1975. Vol. 1. Taylor & Francis. p. 10. ISBN  9780850660937.
  19. ^ a b c Dolan 2013a.
  20. ^ McCarthy, Dennis; Seidelmann, P. Kenneth (2009). TIME from Earth Rotation to Atomic Physics. Weinheim: Wiley-VCH. pp. 244–5.
  21. ^ ROG Learning Team (23 August 2002). "The Prime Meridian at Greenwich". Royal Museums Greenwich. Archived from the original on 7 November 2015. Retrieved 14 June 2012.
  22. ^ Malys, Stephen; Seago, John H.; Palvis, Nikolaos K.; Seidelmann, P. Kenneth; Kaplan, George H. (1 August 2015). "Why the Greenwich meridian moved". Journal of Geodesy. 89 (12): 1263. Bibcode: 2015JGeod..89.1263M. doi: 10.1007/s00190-015-0844-y.
  23. ^ Dolan 2013b.
  24. ^ "Greenwich Meridan, Tracing its History". gpsinformation.net. Archived from the original on 19 December 2017. Retrieved 29 November 2006.
  25. ^ IRM on grounds of Royal Observatory from Google Earth Archived 14 October 2016 at the Wayback Machine Accessed 30 March 2012
  26. ^ "Carrington heliographic coordinates". Archived from the original on 28 June 2011. Retrieved 27 July 2009.
  27. ^ Merton E. Davies, "Surface Coordinates and Cartography of Mercury," Journal of Geophysical Research, Vol. 80, No. 17, 10 June 1975
  28. ^ Merton E. Davies, S. E. Dwornik, D. E. Gault, and R. G. Strom, NASA Atlas of Mercury, NASA Scientific and Technical Information Office, 1978.
  29. ^ Archinal, Brent A.; A'Hearn, Michael F.; Bowell, Edward G.; Conrad, Albert R.; Consolmagno, Guy J.; et al. (2010). "Report of the IAU Working Group on Cartographic Coordinates and Rotational Elements: 2009" (PDF). Celestial Mechanics and Dynamical Astronomy. 109 (2): 101–135. Bibcode: 2011CeMDA.109..101A. doi: 10.1007/s10569-010-9320-4. S2CID  189842666. Archived from the original (PDF) on 4 March 2016. Retrieved 26 September 2018.
  30. ^ Davies, M. E., "Surface Coordinates and Cartography of Mercury," Journal of Geophysical Research, Vol. 80, No. 17, June 10, 1975.
  31. ^ Archinal, Brent A.; A'Hearn, Michael F.; Bowell, Edward L.; Conrad, Albert R.; et al. (2010). "Report of the IAU Working Group on Cartographic Coordinates and Rotational Elements: 2009". Celestial Mechanics and Dynamical Astronomy. 109 (2): 101–135. Bibcode: 2011CeMDA.109..101A. doi: 10.1007/s10569-010-9320-4. ISSN  0923-2958. S2CID  189842666.
  32. ^ "USGS Astrogeology: Rotation and pole position for the Sun and planets (IAU WGCCRE)". Archived from the original on 24 October 2011. Retrieved 22 October 2009.
  33. ^ Merton E. Davies; Colvin, T. R.; Rogers, P. G.; Chodas, P. G.; Sjogren, W. L.; Akim, W. L.; Stepanyantz, E. L.; Vlasova, Z. P.; and Zakharov, A. I.; "The Rotation Period, Direction of the North Pole, and Geodetic Control Network of Venus", Journal of Geophysical Research, vol. 97, no. 8, 1992, pp. 1–14, 151
  34. ^ "USGS Astrogeology: Rotation and pole position for the Sun and planets (IAU WGCCRE)". Archived from the original on 24 October 2011. Retrieved 22 October 2009.
  35. ^ Merton E. Davies, and Berg, R. A.; "Preliminary Control Net of Mars", Journal of Geophysical Research, vol. 76, no. 2, 10 January 1971, pp. 373–393
  36. ^ Archinal, Brent A.; Acton, C. H.; A'Hearn, Michael F.; Conrad, Albert R.; et al. (2018), "Report of the IAU Working Group on Cartographic Coordinates and Rotational Elements: 2015", Celestial Mechanics and Dynamical Astronomy, 130 (22): 22, Bibcode: 2018CeMDA.130...22A, doi: 10.1007/s10569-017-9805-5, S2CID  189844155
  37. ^ Marc Reyman (30 October 2015). "New Maps of Ceres Reveal Topography Surrounding Mysterious 'Bright Spots'". NASA. Retrieved 13 September 2022.
  38. ^ "IAU WGCCRE Coordinate System for Vesta | USGS Astrogeology Science Center". Astrogeology.usgs.gov. 15 November 2013. Retrieved 25 June 2014.
  39. ^ "Planetographic Coordinates". Archived from the original on 15 April 2012. Retrieved 24 May 2017.
  40. ^ Merton E. Davies, Thomas A. Hauge, et al.: Control Networks for the Galilean Satellites: November 1979 R-2532-JPL/NASA
  41. ^ Lopes, R. M. C.; Williams, D. A. (2005). "Io after Galileo". Reports on Progress in Physics. 68 (2): 303–340. Bibcode: 2005RPPh...68..303L. doi: 10.1088/0034-4885/68/2/R02. S2CID  44208045.
  42. ^ "USGS Astrogeology: Rotation and pole position for planetary satellites (IAU WGCCRE)". Archived from the original on 24 October 2011. Retrieved 28 August 2017.
  43. ^ Satellites of Jupiter. (1982:912). United States: University of Arizona Press.
  44. ^ Merton E. Davies, P. G. Rogers, and T. R. Colvin, "A Control Network of Triton," Journal of Geophysical Research, Vo l. 96, E l, pp. 15,675-15,681, 1991.
  45. ^ International Conference Held at Washington for the Purpose of Fixing a Prime Meridian and a Universal Day. October, 1884 Archived 18 December 2021 at the Wayback Machine, pp. 43–51. Project Gutenberg
  46. ^ NGS 2016, PID: HV1847.
  47. ^ NGS 2016, PID: HV1846.
  48. ^ NGS 2016, PID: AH7372.
  49. ^ a b c Hooker 2006, introduction.
  50. ^ a b c Oct. 13, 1884: Greenwich Resolves Subprime Meridian Crisis Archived 1 December 2018 at the Wayback Machine, WIRED, 13 October 2010.
  51. ^ Atlas do Brazil Archived 16 June 2014 at the Wayback Machine, 1909, by Barão Homem de Mello e Francisco Homem de Mello, published in Rio de Janeiro by F. Briguiet & Cia.
  52. ^ a b c "The Project Gutenberg eBook of International Conference Held at Washington for the Purpose of Fixing a Prime Meridian and a Universal Day". Gutenberg.org. 12 February 2006. Archived from the original on 18 December 2021. Retrieved 28 March 2016.
  53. ^ Ancient, used in Ptolemy's Geographia. Later redefined 17° 39 46″ W of Greenwich to be exactly 20° W of Paris. French "submarin" at Washington 1884.
  54. ^ A.R.T. Jonkers; Parallel meridians: Diffusion and change in early modern oceanic reckoning Archived 26 January 2018 at the Wayback Machine, in Noord-Zuid in Oostindisch perspectief, The Hague, 2005, p. 7. Retrieved 2 February 2015.
  55. ^ a b c d e Bartky, Ian R. (2007). One Time Fits All: The Campaigns for Global Uniformity. Stanford University Press. p. 98. ISBN  978-0-8047-5642-6. Archived from the original on 22 January 2023. Retrieved 8 December 2018.
  56. ^ "In search of the lost meridian of Cadiz" Archived 30 November 2019 at the Wayback Machine, El País, 23 December 2016. Retrieved 8 November 2018.
  57. ^ Antonio Lafuente and Manuel Sellés, El Observatorio de Cádiz (1753–1831) Archived 2 June 2020 at the Wayback Machine, Ministerio de Defensa, 1988, p.144, ISBN  84-505-7563-X. (in Spanish)
  58. ^ (in Dutch) Eenheid van tijd in Nederland (Unity of time in the Netherlands) Archived 10 February 2015 at the Wayback Machine, Utrecht University website, retrieved 28 August 2013.
  59. ^ Grids & Datums – Italian Republic Archived 20 November 2012 at the Wayback Machine, asprs.org, Retrieved 10 December 2013.
  60. ^ meridian Archived 14 March 2016 at the Wayback Machine, article from Den Store Danske Encyklopædi
  61. ^ Tolhopff, Johannes (1480). Stellarium (in Latin). Archived from the original on 30 December 2021. Retrieved 30 December 2021. (facsimile, not machine readable)
  62. ^ Zsoldos, Endre (2014). "Stellarium – egy csillagászati kódex Mátyás könyvtárában" [Stellarium - an Astronomical Codex in the Library of King Matthias]. Orpheus Noster (in Hungarian). 5 (4): 64–87.
  63. ^ Szathmáry, László (2002). "Az asztrológia, alkémia és misztika Mátyás király udvarában" [Astrology, alchemy and mysticism in the court of King Matthias.]. Ponticulus Hungaricus (in Hungarian). VI. évfolyam 5. szám. Archived from the original on 18 October 2009. Retrieved 27 December 2018.
  64. ^ "Oradea". Romania Tourism. Archived from the original on 6 February 2015. Retrieved 3 February 2015.
  65. ^ "Romanian astronaut marks 10th anniversary of Prime Meridian Astronomy Club". NineO'Clock. 2015. Archived from the original on 1 October 2017. Retrieved 26 June 2017.
  66. ^ "Meridian Zero csillagászklub" (in Romanian). Archived from the original on 12 April 2009. Retrieved 27 December 2018.
  67. ^ Wilcomb E. Washburn, " The Canary Islands and the Question of the Prime Meridian: The Search for Precision in the Measurement of the Earth Archived 29 May 2007 at the Wayback Machine"
  68. ^ Hilchot Kiddush Hachodesh 11:17
  69. ^ Burgess 1860.

Works cited

External links

From Wikipedia, the free encyclopedia
(Redirected from History of prime meridians)

A prime meridian is an arbitrarily-chosen meridian (a line of longitude) in a geographic coordinate system at which longitude is defined to be 0°. Together, a prime meridian and its anti-meridian (the 180th meridian in a 360°-system) form a great circle. This great circle divides a spheroid, like Earth, into two hemispheres: the Eastern Hemisphere and the Western Hemisphere (for an east-west notational system). For Earth's prime meridian, various conventions have been used or advocated in different regions throughout history. [1] Earth's current international standard prime meridian is the IERS Reference Meridian. It is derived, but differs slightly, from the Greenwich Meridian, the previous standard. [2]

Gerardus Mercator in his Atlas Cosmographicae (1595) used a prime meridian somewhere close to 25°W, passing just to the west of Santa Maria Island in the Azores in the Atlantic Ocean. His 180th meridian runs along the Strait of Anián (Bering Strait)

A prime meridian for a planetary body not tidally locked (or at least not in synchronous rotation) is entirely arbitrary, unlike an equator, which is determined by the axis of rotation. However, for celestial objects that are tidally locked (more specifically, synchronous), their prime meridians are determined by the face always inward of the orbit (a planet facing its star, or a moon facing its planet), just as equators are determined by rotation.

Longitudes for the Earth and Moon are measured from their prime meridian (at 0°) to 180° east and west. For all other Solar System bodies, longitude is measured from 0° (their prime meridian) to 360°. West longitudes are used if the rotation of the body is prograde (or 'direct', like Earth), meaning that its direction of rotation is the same as that of its orbit. East longitudes are used if the rotation is retrograde. [3]

History

Ptolemy's 1st projection, redrawn under Maximus Planudes around 1300, using a prime meridian through the Canary Islands west of Africa, at the left-hand edge of the map. (The obvious central line shown here is the junction of two sheets).

The notion of longitude for Greeks was developed by the Greek Eratosthenes (c. 276 – 195 BCE) in Alexandria, and Hipparchus (c. 190 – 120 BCE) in Rhodes, and applied to a large number of cities by the geographer Strabo (64/63 BCE – c. 24 CE). But it was Ptolemy (c. 90 – 168 CE) who first used a consistent meridian for a world map in his Geographia.

Ptolemy used as his basis the " Fortunate Isles", a group of islands in the Atlantic, which are usually associated with the Canary Islands (13° to 18°W), although his maps correspond more closely to the Cape Verde islands (22° to 25° W). The main point is to be comfortably west of the western tip of Africa (17.5° W) as negative numbers were not yet in use. His prime meridian corresponds to 18° 40' west of Winchester (about 20°W) today. [1] At that time the chief method of determining longitude was by using the reported times of lunar eclipses in different countries.

One of the earliest known descriptions of standard time in India appeared in the 4th century CE astronomical treatise Surya Siddhanta. Postulating a spherical Earth, the book described the thousands years old customs of the prime meridian, or zero longitude, as passing through Avanti, the ancient name for the historic city of Ujjain, and Rohitaka, the ancient name for Rohtak ( 28°54′N 76°38′E / 28.900°N 76.633°E / 28.900; 76.633 (Rohitaka (Rohtak))), a city near the Kurukshetra. [4][ better source needed]

William Grigg's facsimile of the 1529 Spanish Padron Real, from the copy made by Diogo Ribeiro and held by the Vatican Library.

Ptolemy's Geographia was first printed with maps at Bologna in 1477, and many early globes in the 16th century followed his lead. But there was still a hope that a "natural" basis for a prime meridian existed. Christopher Columbus reported (1493) that the compass pointed due north somewhere in mid-Atlantic, and this fact was used in the important Treaty of Tordesillas of 1494, which settled the territorial dispute between Spain and Portugal over newly discovered lands. The Tordesillas line was eventually settled at 370 leagues (2,193 kilometers, 1,362 statute miles, or 1,184 nautical miles) west of Cape Verde. [a] This is shown in the copies of Spain's Padron Real made by Diogo Ribeiro in 1527 and 1529. São Miguel Island (25.5°W) in the Azores was still used for the same reason as late as 1594 by Christopher Saxton, although by then it had been shown that the zero magnetic declination line did not follow a line of longitude. [8]

1571 Africa map by Abraham Ortelius, with Cape Verde as its prime meridian.
1682 map of East Asia by Giacomo Cantelli, with Cape Verde as its prime meridian; Japan is thus located around 180° E.

In 1541, Mercator produced his famous 41 cm terrestrial globe and drew his prime meridian precisely through Fuerteventura (14°1'W) in the Canaries. His later maps used the Azores, following the magnetic hypothesis. But by the time that Ortelius produced the first modern atlas in 1570, other islands such as Cape Verde were coming into use. In his atlas longitudes were counted from 0° to 360°, not 180°W to 180°E as is usual today. This practice was followed by navigators well into the 18th century. [9] In 1634, Cardinal Richelieu used the westernmost island of the Canaries, El Hierro, 19° 55' west of Paris, as the choice of meridian. The geographer Delisle decided to round this off to 20°, so that it simply became the meridian of Paris disguised. [10]

In the early 18th century the battle was on to improve the determination of longitude at sea, leading to the development of the marine chronometer by John Harrison. But it was the development of accurate star charts, principally by the first British Astronomer Royal, John Flamsteed between 1680 and 1719 and disseminated by his successor Edmund Halley, that enabled navigators to use the lunar method of determining longitude more accurately using the octant developed by Thomas Godfrey and John Hadley. [11]

In the 18th century most countries in Europe adapted their own prime meridian, usually through their capital, hence in France the Paris meridian was prime, in Prussia it was the Berlin meridian, in Denmark the Copenhagen meridian, and in United Kingdom the Greenwich meridian.

Between 1765 and 1811, Nevil Maskelyne published 49 issues of the Nautical Almanac based on the meridian of the Royal Observatory, Greenwich. "Maskelyne's tables not only made the lunar method practicable, they also made the Greenwich meridian the universal reference point. Even the French translations of the Nautical Almanac retained Maskelyne's calculations from Greenwich – in spite of the fact that every other table in the Connaissance des Temps considered the Paris meridian as the prime." [12]

In 1884, at the International Meridian Conference in Washington, D.C., 22 countries voted to adopt the Greenwich meridian as the prime meridian of the world. [13] The French argued for a neutral line, mentioning the Azores and the Bering Strait, but eventually abstained and continued to use the Paris meridian until 1911.

The current international standard Prime Meridian is the IERS Reference Meridian. The International Hydrographic Organization adopted an early version of the IRM in 1983 for all nautical charts. [14] It was adopted for air navigation by the International Civil Aviation Organization on 3 March 1989. [15]

International prime meridian

Since 1984, the international standard for the Earth's prime meridian is the IERS Reference Meridian. Between 1884 and 1984, the meridian of Greenwich was the world standard. These meridians are physically very close to each other.

Prime meridian at Greenwich

The line of the Greenwich meridian at the Royal Observatory, Greenwich

In October 1884 the Greenwich Meridian was selected by delegates (forty-one delegates representing twenty-five nations) to the International Meridian Conference held in Washington, D.C., United States to be the common zero of longitude and standard of time reckoning throughout the world. [16] [b]

The position of the historic prime meridian, based at the Royal Observatory, Greenwich, was established by Sir George Airy in 1851. It was defined by the location of the Airy Transit Circle ever since the first observation he took with it. [18] Prior to that, it was defined by a succession of earlier transit instruments, the first of which was acquired by the second Astronomer Royal, Edmond Halley in 1721. It was set up in the extreme north-west corner of the Observatory between Flamsteed House and the Western Summer House. This spot, now subsumed into Flamsteed House, is roughly 43 metres to the west of the Airy Transit Circle, a distance equivalent to roughly 2 seconds of longitude. [19] It was Airy's transit circle that was adopted in principle (with French delegates, who pressed for adoption of the Paris meridian abstaining) as the Prime Meridian of the world at the 1884 International Meridian Conference. [20] [21]

All of these Greenwich meridians were located via an astronomic observation from the surface of the Earth, oriented via a plumb line along the direction of gravity at the surface. This astronomic Greenwich meridian was disseminated around the world, first via the lunar distance method, then by chronometers carried on ships, then via telegraph lines carried by submarine communications cables, then via radio time signals. One remote longitude ultimately based on the Greenwich meridian using these methods was that of the North American Datum 1927 or NAD27, an ellipsoid whose surface best matches mean sea level under the United States.

IERS Reference Meridian

Beginning in 1973 the International Time Bureau and later the International Earth Rotation and Reference Systems Service changed from reliance on optical instruments like the Airy Transit Circle to techniques such as lunar laser ranging, satellite laser ranging, and very-long-baseline interferometry. The new techniques resulted in the IERS Reference Meridian, the plane of which passes through the centre of mass of the Earth. This differs from the plane established by the Airy transit, which is affected by vertical deflection (the local vertical is affected by influences such as nearby mountains). The change from relying on the local vertical to using a meridian based on the centre of the Earth caused the modern prime meridian to be 5.3″ east of the astronomic Greenwich prime meridian through the Airy Transit Circle. At the latitude of Greenwich, this amounts to 102 metres. [22] This was officially accepted by the Bureau International de l'Heure (BIH) in 1984 via its BTS84 (BIH Terrestrial System) that later became WGS84 (World Geodetic System 1984) and the various International Terrestrial Reference Frames (ITRFs).

Due to the movement of Earth's tectonic plates, the line of 0° longitude along the surface of the Earth has slowly moved toward the west from this shifted position by a few centimetres; that is, towards the Airy Transit Circle (or the Airy Transit Circle has moved toward the east, depending on your point of view) since 1984 (or the 1960s). With the introduction of satellite technology, it became possible to create a more accurate and detailed global map. With these advances there also arose the necessity to define a reference meridian that, whilst being derived from the Airy Transit Circle, would also take into account the effects of plate movement and variations in the way that the Earth was spinning. [23] As a result, the IERS Reference Meridian was established and is commonly used to denote the Earth's prime meridian (0° longitude) by the International Earth Rotation and Reference Systems Service, which defines and maintains the link between longitude and time. Based on observations to satellites and celestial compact radio sources (quasars) from various coordinated stations around the globe, Airy's transit circle drifts northeast about 2.5 centimetres per year relative to this Earth-centred 0° longitude.

It is also the reference meridian of the Global Positioning System operated by the United States Department of Defense, and of WGS84 and its two formal versions, the ideal International Terrestrial Reference System (ITRS) and its realization, the International Terrestrial Reference Frame (ITRF). [24] [25] [c] A current convention on the Earth uses the line of longitude 180° opposite the IRM as the basis for the International Date Line.

List of places

On Earth, starting at the North Pole and heading south to the South Pole, the IERS Reference Meridian (as of 2016) passes through:

Co-ordinates
(approximate)
Country, territory or sea Notes
90°0′N 0°0′E / 90.000°N 0.000°E / 90.000; 0.000 (North Pole) Arctic Ocean
85°46′N 0°0′E / 85.767°N 0.000°E / 85.767; 0.000 (EEZ of Greenland (Denmark)) Exclusive Economic Zone (EEZ) of Greenland ( Denmark)
81°39′N 0°0′E / 81.650°N 0.000°E / 81.650; 0.000 (Greenland Sea) Greenland Sea
80°29′N 0°0′E / 80.483°N 0.000°E / 80.483; 0.000 (EEZ of Svalbard (Norway)) EEZ of Svalbard ( Norway)
76°11′N 0°0′E / 76.183°N 0.000°E / 76.183; 0.000 (International waters) International waters
73°44′N 0°0′E / 73.733°N 0.000°E / 73.733; 0.000 (EEZ of Jan Mayen) EEZ of Jan Mayen ( Norway)
72°53′N 0°0′E / 72.883°N 0.000°E / 72.883; 0.000 (Norwegian Sea) Norwegian Sea
69°7′N 0°0′E / 69.117°N 0.000°E / 69.117; 0.000 (International waters) International waters
64°42′N 0°0′E / 64.700°N 0.000°E / 64.700; 0.000 (EEZ of Norway) EEZ of Norway
63°29′N 0°0′E / 63.483°N 0.000°E / 63.483; 0.000 (EEZ of Great Britain) EEZ of Great Britain
61°0′N 0°0′E / 61.000°N 0.000°E / 61.000; 0.000 (North Sea) North Sea
53°46′N 0°0′E / 53.767°N 0.000°E / 53.767; 0.000 (United Kingdom)   United Kingdom From Tunstall in East Riding to Peacehaven, passing through Greenwich
50°47′N 0°0′E / 50.783°N 0.000°E / 50.783; 0.000 (English Channel) English Channel EEZ of Great Britain
50°14′N 0°0′E / 50.233°N 0.000°E / 50.233; 0.000 (EEZ of France) English Channel EEZ of France
49°20′N 0°0′E / 49.333°N 0.000°E / 49.333; 0.000 (France)   France From Villers-sur-Mer to Gavarnie
42°41′N 0°0′E / 42.683°N 0.000°E / 42.683; 0.000 (Spain)   Spain From Cilindro de Marboré to Castellón de la Plana
39°56′N 0°0′E / 39.933°N 0.000°E / 39.933; 0.000 (Mediterranean Sea) Mediterranean Sea Gulf of Valencia; EEZ of Spain
38°52′N 0°0′E / 38.867°N 0.000°E / 38.867; 0.000 (Spain)   Spain From El Verger to Calp
38°38′N 0°0′E / 38.633°N 0.000°E / 38.633; 0.000 (Mediterranean Sea) Mediterranean Sea EEZ of Spain
37°1′N 0°0′E / 37.017°N 0.000°E / 37.017; 0.000 (EEZ of Algeria) Mediterranean Sea EEZ of Algeria
35°50′N 0°0′E / 35.833°N 0.000°E / 35.833; 0.000 (Algeria)   Algeria From Stidia to Algeria-Mali border near Bordj Badji Mokhtar
21°52′N 0°0′E / 21.867°N 0.000°E / 21.867; 0.000 (Mali)   Mali Passing through Gao
15°00′N 0°0′E / 15.000°N 0.000°E / 15.000; 0.000 (Burkina Faso)   Burkina Faso For about 432 km, running through Cinkassé.
11°7′N 0°0′E / 11.117°N 0.000°E / 11.117; 0.000 (Togo)   Togo For about 3.4 km
11°6′N 0°0′E / 11.100°N 0.000°E / 11.100; 0.000 (Ghana)   Ghana For about 16 km
10°58′N 0°0′E / 10.967°N 0.000°E / 10.967; 0.000 (Togo)   Togo For about 39 km
10°37′N 0°0′E / 10.617°N 0.000°E / 10.617; 0.000 (Ghana)   Ghana From the Togo-Ghana border near Bunkpurugu to Tema
Passing through Lake Volta at 7°46′N 0°0′E / 7.767°N 0.000°E / 7.767; 0.000 (Lake Volta)
5°37′N 0°0′E / 5.617°N 0.000°E / 5.617; 0.000 (EEZ of Ghana in Atlantic Ocean) Atlantic Ocean EEZ of Ghana
1°58′N 0°0′E / 1.967°N 0.000°E / 1.967; 0.000 (International waters) International waters
0°0′N 0°0′E / 0.000°N 0.000°E / 0.000; 0.000 (Equator) Passing through the Equator (see Null Island)
51°43′S 0°0′E / 51.717°S 0.000°E / -51.717; 0.000 (EEZ of Bouvet Island) EEZ of Bouvet Island ( Norway)
57°13′S 0°0′E / 57.217°S 0.000°E / -57.217; 0.000 (International waters) International waters
60°0′S 0°0′E / 60.000°S 0.000°E / -60.000; 0.000 (Southern Ocean) Southern Ocean International waters
69°36′S 0°0′E / 69.600°S 0.000°E / -69.600; 0.000 (Antarctica) Antarctica Queen Maud Land, claimed by   Norway
90°0′S 0°0′E / 90.000°S 0.000°E / -90.000; 0.000 (Amundsen–Scott South Pole Station) Antarctica Amundsen–Scott South Pole Station, South Pole

Prime meridian on other celestial bodies

As on the Earth, prime meridians must be arbitrarily defined. Often a landmark such as a crater is used; other times a prime meridian is defined by reference to another celestial object, or by magnetic fields. The prime meridians of the following planetographic systems have been defined:

  • Two different heliographic coordinate systems are used on the Sun. The first is the Carrington heliographic coordinate system. In this system, the prime meridian passes through the center of the solar disk as seen from the Earth on 9 November 1853, which is when the English astronomer Richard Christopher Carrington started his observations of sunspots. [26] The second is the Stonyhurst heliographic coordinates system, originated at Stonyhurst Observatory in Lancashire, England.
  • In 1975 the prime meridian of Mercury was defined [27] [28] to be 20° east of the crater Hun Kal. [29] This meridian was chosen because it runs through the point on Mercury's equator where the average temperature is highest (due to the planet's rotation and orbit, the sun briefly retrogrades at noon at this point during perihelion, giving it more sunlight). [30] [31] [32]
  • Defined [33] in 1992, the prime meridian of Venus passes through the central peak in the crater Ariadne, chosen arbitrarily. [34]
  • The prime meridian of the Moon lies directly in the middle of the face of the Moon visible from Earth and passes near the crater Bruce.
  • The prime meridian of Mars was established in 1971 [35] and passes through the center of the crater Airy-0, although it is fixed by the longitude of the Viking 1 lander, which is defined to be 47.95137°W. [36]
  • The prime meridian on Ceres runs through the Kait crater, which was arbitrarily chosen because it is near the equator (about 2° south). [37]
  • The prime meridian on 4 Vesta is 4 degrees east of the crater Claudia, chosen because it is sharply defined. [38]
  • Jupiter has several coordinate systems because its cloud tops—the only part of the planet visible from space—rotate at different rates depending on latitude. [39] It is unknown whether Jupiter has any internal solid surface that would enable a more Earth-like coordinate system. System I and System II coordinates are based on atmospheric rotation, and System III coordinates use Jupiter's magnetic field. The prime meridians of Jupiter's four Galilean moons were established in 1979. [40]
    • Europa's prime meridian is defined such that the crater Cilix is at 182° W. The 0° longitude runs through the middle of the face that is always turned towards Jupiter.
    • Io's prime meridian, like that of Earth's moon, is defined so that it runs through the middle of the face that is always turned towards Jupiter (the near side, known as the subjovian hemisphere). [41]
    • Ganymede's prime meridian is defined such that the crater Anat is at 128° W, and the 0° longitude runs through the middle of the subjovian hemisphere. [42]
    • Callisto's prime meridian is defined such that the crater Saga is at 326° W. [43]
  • Titan is the largest moon of Saturn and, like the Earth's moon, always has the same face towards Saturn, and so the middle of that face is 0 longitude.
  • Like Jupiter, Neptune is a gas giant, so any surface is obscured by clouds. The prime meridian of its largest moon, Triton, was established in 1991. [44]
  • Pluto's prime meridian is defined as the meridian passing through the center of the face that is always towards Charon, its largest moon, as the two are tidally locked to each other. Charon's prime meridian is similarly defined as the meridian always facing directly toward Pluto.

List of historic prime meridians on Earth

Locality Modern longitude Meridian name Image Comment
Bering Strait 168°30 W
Line across the Earth
168°
168th meridian west
Offered in 1884 as possibility for a neutral prime meridian by Pierre Janssen at the International Meridian Conference [45]
Washington, D.C. 77°0356.07″ W (1897) or 77°0402.24″ W (NAD 27)[ clarification needed] or 77°0401.16″ W (NAD 83) New Naval Observatory meridian
Line across the Earth
77°
77th meridian west
77°0248.0″ W, 77°0302.3″, 77°0306.119″ W or 77°0306.276″ W (both presumably NAD 27). If NAD27, the latter would be 77°0305.194″ W (NAD 83) Old Naval Observatory meridian
77°0211.56299″ W (NAD 83), [46] 77°0211.55811″ W (NAD 83), [47] 77°0211.58325″ W (NAD 83) [48] (three different monuments originally intended to be on the White House meridian) White House meridian
77°0032.6″ W (NAD 83) Capitol meridian
Philadelphia 75° 10 12″ W
Line across the Earth
75°
75th meridian west
[49] [50]
Rio de Janeiro 43° 10 19″ W
Line across the Earth
43°
43rd meridian west
[51]
Fortunate Isles / Azores 25° 40 32″ W
Line across the Earth
25°
25th meridian west
Used until the Middle Ages, proposed as one possible neutral meridian by Pierre Janssen at the International Meridian Conference [52]
El Hierro (Ferro),
Canary Islands
18° 03 W,
later redefined as
17° 39 46″ W
Ferro meridian
Line across the Earth
18°
18th meridian west
[53]
Tenerife 16°3822″ W Tenerife meridian
Line across the Earth
16°
16th meridian west
Rose to prominence with Dutch cartographers and navigators after they abandoned the idea of a magnetic meridian [54]
Lisbon 9° 07 54.862″ W
Line across the Earth
9th meridian west
[55]
Cadiz 6° 17 35.4" W Cadiz meridian
Line across the Earth
6th meridian west
Royal Observatory in southeast tower of Castillo de la Villa, used 1735–1850 by Spanish Navy. [56] [57]
Madrid 3° 41 16.58″ W
Line across the Earth
3rd meridian west
[55]
Kew 0° 00 19.0″ W Prime Meridian (prior to Greenwich)
Line across the Earth
Prime meridian
Located at King George III's Kew Observatory
Greenwich 0° 00 05.33″ W United Kingdom Ordnance Survey Zero Meridian Bradley Meridian [19]
0° 00 05.3101″ W Greenwich meridian Airy Meridian [19]
0° 00 00.00″ IERS Reference Meridian
Paris 2° 20 14.025″ E Paris meridian
Line across the Earth
2nd meridian east
Brussels 4° 22 4.71″ E
Line across the Earth
4th meridian east
[55]
Antwerp 4° 24 E Antwerp meridian
Amsterdam 4° 53 E Through the Westerkerk in Amsterdam; used to define the legal time in the Netherlands from 1909 to 1937 [58]
Pisa 10° 24 E
Line across the Earth
10°
10th meridian east
[49]
Oslo (Kristiania) 10° 43 22.5″ E [49] [50]
Florence 11°15 E Florence meridian
Line across the Earth
11°
11th meridian east
Used in the Peters projection, 180° from a meridian running through the Bering Strait
Rome 12° 27 08.4″ E Meridian of Monte Mario
Line across the Earth
12°
12th meridian east
Used in Roma 40 Datum [59]
Copenhagen 12° 34 32.25″ E Rundetårn [60]
Naples 14° 15 E
Line across the Earth
14°
14th meridian east
[52]
Pressburg 17° 06 03″ E Meridianus Posoniensis
Line across the Earth
17°
17th meridian east
Used by Sámuel Mikoviny
Stockholm 18° 03 29.8″ E
Line across the Earth
18°
18th meridian east
At the Stockholm Observatory [55]
Buda 19° 03 37″ E Meridianu(s) Budense
Line across the Earth
19°
19th meridian east
Used between 1469 and 1495; introduced by Regiomontanus, used by Marcin Bylica, Galeotto Marzio, Miklós Erdélyi (1423–1473), Johannes Tolhopff (c. 1445–1503), Johannes Muntz. Set in the royal castle (and observatory) of Buda. [d]
Kraków 19° 57 21.43″ E Kraków meridian at the Old Kraków Observatory at the Śniadecki' College; mentioned also in Nicolaus Copernicus's work On the Revolutions of the Heavenly Spheres.
Warsaw 21° 00 42″ E Warsaw meridian
Line across the Earth
21°
21st meridian east
[55]
Várad 21° 55 16″ E Tabulae Varadienses
Line across the Earth
21°
21st meridian east
[64] Between 1464 and 1667, a prime meridian was set in the Fortress of Oradea (Varadinum at the time) by Georg von Peuerbach. [65] In his logbook Columbus stated, he had one copy of Tabulae Varadienses (Tabula Varadiensis or Tabulae directionum) on board to calculate the actual meridian based on the position of the Moon, in correlation to Várad. Amerigo Vespucci also recalled, how was he acquired the knowledge to calculate meridians by means of these tables. [66]
Alexandria 29° 53 E Meridian of Alexandria
Line across the Earth
29°
29th meridian east
The meridian of Ptolemy's Almagest.
Saint Petersburg 30° 19 42.09″ E Pulkovo meridian
Line across the Earth
30°
30th meridian east
Great Pyramid of Giza 31° 08 03.69″ E
Line across the Earth
31°
31st meridian east
1884 [67]
Jerusalem 35° 13 47.1″ E
Line across the Earth
35°
35th meridian east
[50]
Mecca 39° 49 34″ E
Line across the Earth
39°
39th meridian east
See also Mecca Time
Approx. 59° E
Line across the Earth
59°
59th meridian east
Maimonides [68] calls this point אמצע היישוב, "the middle of the habitation", i.e. the habitable hemisphere. Evidently this was a convention accepted by Arab geographers of his day.
Ujjain 75° 47 E
Line across the Earth
75°
75th meridian east
Used from 4th century CE Indian astronomy and calendars(see also Time in India). [69]
Kyoto 136° 14 E
Line across the Earth
136°
136th meridian east
Used in 18th and 19th (officially 1779–1871) century Japanese maps. Exact place unknown, but in "Kairekisyo" in Nishigekkoutyou-town in Kyoto, then the capital.[ citation needed]
~ 180
Line across the Earth
180°
180th meridian
Opposite of Greenwich, proposed 13 October 1884 on the International Meridian Conference by Sandford Fleming [52]

See also

Notes

  1. ^ These figures use the legua náutica (nautical league) of four Roman miles totalling 5.926 km (3.682 mi), which was used by Spain during the 15th, 16th, and 17th centuries for navigation. [5] In 1897 Henry Harrise noted that Jaime Ferrer, the expert consulted by King Ferdinand and Queen Isabella, stated that a league was four miles of six stades each. [6] Modern scholars agree that the geographic stade was the Roman or Italian stade, not any of several other Greek stades, supporting these figures. [7] Harrise is in the minority when he uses the stade of 192.27 m (630.8 ft) marked within the stadium at Olympia, Greece, resulting in a league (32 stades) of 6.153 km (3.823 mi), 3.8% larger.
  2. ^ Voting took place on 13 October and the resolutions were adopted on 22 October 1884. [17] The modern prime meridian, the IERS Reference Meridian, is placed very near this meridian. [13]
  3. ^ The astronomic latitude of the Royal Observatory is 51°2838″N whereas its latitude on the European Terrestrial Reference Frame (1989) datum is 51°2840.1247″N.
  4. ^ When Tolhopff handed over his book, titled Stellarium (1480), [61] to King Matthias Corvinus, he emphasized that he had used the meridian of Buda for his calculations. The German physician, Johannes Müntz used it the same way in his 1495 calendar. However, in the second edition, he used the Vienna meridian. [62] [63]

References

  1. ^ a b Norgate & Norgate 2006.
  2. ^ "What is the Prime Meridian and why is it in Greenwich?". Royal Museums Greeenwich. Archived from the original on 13 December 2021. Retrieved 13 December 2021. The IRM is the only meridian that may now be described as the prime meridian of the world, as it defines 0° longitude by international agreement. The IRM passes 102.5 metres to the east of the historic Prime Meridian of the World at the latitude of the Airy Transit Circle here. The entire Observatory and the historic Prime Meridian now lie to the west of the true prime meridian.
  3. ^ Archimal, B. A. (2015), Report of the IAU Working Group on Cartographic Coordinates and Rotational Elements: 2015 (PDF), p. 27 of 46, archived (PDF) from the original on 6 August 2019, retrieved 6 August 2019, The range of longitudes shall extend from 0° to 360°. Thus, west longitudes are used when the rotation is direct, and east longitudes are used when the rotation is retrograde. ... The Earth, Sun, and Moon do not traditionally follow this definition. Their rotations are direct and longitudes run both east and west 180°, or positive to the east 360°.
  4. ^ Schmidt, Olaf H. (1944). "The Computation of the Length of Daylight in Hindu Astronomy". Isis. 35 (3). The University of Chicago Press: 205–211. doi: 10.1086/358709. JSTOR  330729. S2CID  145178197. Archived from the original on 26 January 2022.
  5. ^ Chardon, Roland (1980). "The linear league in North America". Annals of the Association of American Geographers. 70 (2): 129–153 [pp. 142, 144, 151]. doi: 10.1111/j.1467-8306.1980.tb01304.x. JSTOR  2562946.
  6. ^ Harrisse, Henry (1897). The Diplomatic History of America: Its first chapter 1452—1493—1494. London: Stevens. pp. 85–97, 176–190. ISBN  9780697000071. OCLC  1101220811.
  7. ^ Engels, Donald (1985). "The length of Eratosthenes' stade". American Journal of Philology. 106 (3): 298–311. doi: 10.2307/295030. JSTOR  295030.
  8. ^ Hooker 2006.
  9. ^ e.g. Jacob Roggeveen in 1722 reported the longitude of Easter Island as 268° 45' (starting from Fuerteventura) in the Extract from the Official log of Jacob Roggeveen reproduced in Bolton Glanville Corney, ed. (1908), The voyage of Don Felipe Gonzalez to Easter Island in 1770-1, Hakluyt Society, p. 3, retrieved 13 January 2013
  10. ^ Speech by Pierre Janssen, director of the Paris observatory, at the first session of the Meridian Conference. Archived 18 December 2021 at the Wayback Machine
  11. ^ Sobel & Andrewes 1998, pp. 110–115.
  12. ^ Sobel & Andrewes 1998, pp. 197–199.
  13. ^ a b "What is the Prime Meridian - and why is it in Greenwich? | Who decided that the Prime Meridian should be in Greenwich?". Royal Museums Greenwich. n.d. Archived from the original on 5 January 2022. Retrieved 28 December 2021.
  14. ^ "A manual on the technical aspects of the United Nations Convention on the Law of the Sea – 1982" (PDF). Archived (PDF) from the original on 10 September 2008. Retrieved 23 July 2008. (4.89 MB) Section 2.4.4.
  15. ^ WGS 84 Implementation Manual Archived 3 October 2008 at the Wayback Machine page i, 1998
  16. ^ International Conference Held at Washington for the Purpose of Fixing a Prime Meridian and a Universal Day. October, 1884. Protocols of the proceedings. Project Gutenberg. 1884. Archived from the original on 18 December 2021. Retrieved 30 November 2012.
  17. ^ Howse 1997, pp. 12, 137
  18. ^ Forbes, Eric Gray (1975). Greenwich Observatory ... the story of Britain's oldest scientific institution, the Royal Observatory at Greenwich and Herstmonceux, 1675–1975. Vol. 1. Taylor & Francis. p. 10. ISBN  9780850660937.
  19. ^ a b c Dolan 2013a.
  20. ^ McCarthy, Dennis; Seidelmann, P. Kenneth (2009). TIME from Earth Rotation to Atomic Physics. Weinheim: Wiley-VCH. pp. 244–5.
  21. ^ ROG Learning Team (23 August 2002). "The Prime Meridian at Greenwich". Royal Museums Greenwich. Archived from the original on 7 November 2015. Retrieved 14 June 2012.
  22. ^ Malys, Stephen; Seago, John H.; Palvis, Nikolaos K.; Seidelmann, P. Kenneth; Kaplan, George H. (1 August 2015). "Why the Greenwich meridian moved". Journal of Geodesy. 89 (12): 1263. Bibcode: 2015JGeod..89.1263M. doi: 10.1007/s00190-015-0844-y.
  23. ^ Dolan 2013b.
  24. ^ "Greenwich Meridan, Tracing its History". gpsinformation.net. Archived from the original on 19 December 2017. Retrieved 29 November 2006.
  25. ^ IRM on grounds of Royal Observatory from Google Earth Archived 14 October 2016 at the Wayback Machine Accessed 30 March 2012
  26. ^ "Carrington heliographic coordinates". Archived from the original on 28 June 2011. Retrieved 27 July 2009.
  27. ^ Merton E. Davies, "Surface Coordinates and Cartography of Mercury," Journal of Geophysical Research, Vol. 80, No. 17, 10 June 1975
  28. ^ Merton E. Davies, S. E. Dwornik, D. E. Gault, and R. G. Strom, NASA Atlas of Mercury, NASA Scientific and Technical Information Office, 1978.
  29. ^ Archinal, Brent A.; A'Hearn, Michael F.; Bowell, Edward G.; Conrad, Albert R.; Consolmagno, Guy J.; et al. (2010). "Report of the IAU Working Group on Cartographic Coordinates and Rotational Elements: 2009" (PDF). Celestial Mechanics and Dynamical Astronomy. 109 (2): 101–135. Bibcode: 2011CeMDA.109..101A. doi: 10.1007/s10569-010-9320-4. S2CID  189842666. Archived from the original (PDF) on 4 March 2016. Retrieved 26 September 2018.
  30. ^ Davies, M. E., "Surface Coordinates and Cartography of Mercury," Journal of Geophysical Research, Vol. 80, No. 17, June 10, 1975.
  31. ^ Archinal, Brent A.; A'Hearn, Michael F.; Bowell, Edward L.; Conrad, Albert R.; et al. (2010). "Report of the IAU Working Group on Cartographic Coordinates and Rotational Elements: 2009". Celestial Mechanics and Dynamical Astronomy. 109 (2): 101–135. Bibcode: 2011CeMDA.109..101A. doi: 10.1007/s10569-010-9320-4. ISSN  0923-2958. S2CID  189842666.
  32. ^ "USGS Astrogeology: Rotation and pole position for the Sun and planets (IAU WGCCRE)". Archived from the original on 24 October 2011. Retrieved 22 October 2009.
  33. ^ Merton E. Davies; Colvin, T. R.; Rogers, P. G.; Chodas, P. G.; Sjogren, W. L.; Akim, W. L.; Stepanyantz, E. L.; Vlasova, Z. P.; and Zakharov, A. I.; "The Rotation Period, Direction of the North Pole, and Geodetic Control Network of Venus", Journal of Geophysical Research, vol. 97, no. 8, 1992, pp. 1–14, 151
  34. ^ "USGS Astrogeology: Rotation and pole position for the Sun and planets (IAU WGCCRE)". Archived from the original on 24 October 2011. Retrieved 22 October 2009.
  35. ^ Merton E. Davies, and Berg, R. A.; "Preliminary Control Net of Mars", Journal of Geophysical Research, vol. 76, no. 2, 10 January 1971, pp. 373–393
  36. ^ Archinal, Brent A.; Acton, C. H.; A'Hearn, Michael F.; Conrad, Albert R.; et al. (2018), "Report of the IAU Working Group on Cartographic Coordinates and Rotational Elements: 2015", Celestial Mechanics and Dynamical Astronomy, 130 (22): 22, Bibcode: 2018CeMDA.130...22A, doi: 10.1007/s10569-017-9805-5, S2CID  189844155
  37. ^ Marc Reyman (30 October 2015). "New Maps of Ceres Reveal Topography Surrounding Mysterious 'Bright Spots'". NASA. Retrieved 13 September 2022.
  38. ^ "IAU WGCCRE Coordinate System for Vesta | USGS Astrogeology Science Center". Astrogeology.usgs.gov. 15 November 2013. Retrieved 25 June 2014.
  39. ^ "Planetographic Coordinates". Archived from the original on 15 April 2012. Retrieved 24 May 2017.
  40. ^ Merton E. Davies, Thomas A. Hauge, et al.: Control Networks for the Galilean Satellites: November 1979 R-2532-JPL/NASA
  41. ^ Lopes, R. M. C.; Williams, D. A. (2005). "Io after Galileo". Reports on Progress in Physics. 68 (2): 303–340. Bibcode: 2005RPPh...68..303L. doi: 10.1088/0034-4885/68/2/R02. S2CID  44208045.
  42. ^ "USGS Astrogeology: Rotation and pole position for planetary satellites (IAU WGCCRE)". Archived from the original on 24 October 2011. Retrieved 28 August 2017.
  43. ^ Satellites of Jupiter. (1982:912). United States: University of Arizona Press.
  44. ^ Merton E. Davies, P. G. Rogers, and T. R. Colvin, "A Control Network of Triton," Journal of Geophysical Research, Vo l. 96, E l, pp. 15,675-15,681, 1991.
  45. ^ International Conference Held at Washington for the Purpose of Fixing a Prime Meridian and a Universal Day. October, 1884 Archived 18 December 2021 at the Wayback Machine, pp. 43–51. Project Gutenberg
  46. ^ NGS 2016, PID: HV1847.
  47. ^ NGS 2016, PID: HV1846.
  48. ^ NGS 2016, PID: AH7372.
  49. ^ a b c Hooker 2006, introduction.
  50. ^ a b c Oct. 13, 1884: Greenwich Resolves Subprime Meridian Crisis Archived 1 December 2018 at the Wayback Machine, WIRED, 13 October 2010.
  51. ^ Atlas do Brazil Archived 16 June 2014 at the Wayback Machine, 1909, by Barão Homem de Mello e Francisco Homem de Mello, published in Rio de Janeiro by F. Briguiet & Cia.
  52. ^ a b c "The Project Gutenberg eBook of International Conference Held at Washington for the Purpose of Fixing a Prime Meridian and a Universal Day". Gutenberg.org. 12 February 2006. Archived from the original on 18 December 2021. Retrieved 28 March 2016.
  53. ^ Ancient, used in Ptolemy's Geographia. Later redefined 17° 39 46″ W of Greenwich to be exactly 20° W of Paris. French "submarin" at Washington 1884.
  54. ^ A.R.T. Jonkers; Parallel meridians: Diffusion and change in early modern oceanic reckoning Archived 26 January 2018 at the Wayback Machine, in Noord-Zuid in Oostindisch perspectief, The Hague, 2005, p. 7. Retrieved 2 February 2015.
  55. ^ a b c d e Bartky, Ian R. (2007). One Time Fits All: The Campaigns for Global Uniformity. Stanford University Press. p. 98. ISBN  978-0-8047-5642-6. Archived from the original on 22 January 2023. Retrieved 8 December 2018.
  56. ^ "In search of the lost meridian of Cadiz" Archived 30 November 2019 at the Wayback Machine, El País, 23 December 2016. Retrieved 8 November 2018.
  57. ^ Antonio Lafuente and Manuel Sellés, El Observatorio de Cádiz (1753–1831) Archived 2 June 2020 at the Wayback Machine, Ministerio de Defensa, 1988, p.144, ISBN  84-505-7563-X. (in Spanish)
  58. ^ (in Dutch) Eenheid van tijd in Nederland (Unity of time in the Netherlands) Archived 10 February 2015 at the Wayback Machine, Utrecht University website, retrieved 28 August 2013.
  59. ^ Grids & Datums – Italian Republic Archived 20 November 2012 at the Wayback Machine, asprs.org, Retrieved 10 December 2013.
  60. ^ meridian Archived 14 March 2016 at the Wayback Machine, article from Den Store Danske Encyklopædi
  61. ^ Tolhopff, Johannes (1480). Stellarium (in Latin). Archived from the original on 30 December 2021. Retrieved 30 December 2021. (facsimile, not machine readable)
  62. ^ Zsoldos, Endre (2014). "Stellarium – egy csillagászati kódex Mátyás könyvtárában" [Stellarium - an Astronomical Codex in the Library of King Matthias]. Orpheus Noster (in Hungarian). 5 (4): 64–87.
  63. ^ Szathmáry, László (2002). "Az asztrológia, alkémia és misztika Mátyás király udvarában" [Astrology, alchemy and mysticism in the court of King Matthias.]. Ponticulus Hungaricus (in Hungarian). VI. évfolyam 5. szám. Archived from the original on 18 October 2009. Retrieved 27 December 2018.
  64. ^ "Oradea". Romania Tourism. Archived from the original on 6 February 2015. Retrieved 3 February 2015.
  65. ^ "Romanian astronaut marks 10th anniversary of Prime Meridian Astronomy Club". NineO'Clock. 2015. Archived from the original on 1 October 2017. Retrieved 26 June 2017.
  66. ^ "Meridian Zero csillagászklub" (in Romanian). Archived from the original on 12 April 2009. Retrieved 27 December 2018.
  67. ^ Wilcomb E. Washburn, " The Canary Islands and the Question of the Prime Meridian: The Search for Precision in the Measurement of the Earth Archived 29 May 2007 at the Wayback Machine"
  68. ^ Hilchot Kiddush Hachodesh 11:17
  69. ^ Burgess 1860.

Works cited

External links


Videos

Youtube | Vimeo | Bing

Websites

Google | Yahoo | Bing

Encyclopedia

Google | Yahoo | Bing

Facebook