The observatory was commissioned in 1675 by
King Charles II, with the
foundation stone being laid on 10 August. The old hilltop site of
Greenwich Castle was chosen by
Sir Christopher Wren, a former
Savilian Professor of Astronomy; as
Greenwich Park was a royal estate, no new land needed to be bought.[3] At that time the king also created the position of
Astronomer Royal, to serve as the director of the observatory and to "apply himself with the most exact care and diligence to the rectifying of the tables of the motions of the heavens, and the places of the fixed stars, so as to find out the so much desired longitude of places for the perfecting of the art of navigation." He appointed
John Flamsteed as the first Astronomer Royal. The building was completed in the summer of 1676.[4] The building was often called "Flamsteed House", in reference to its first occupant.
The scientific work of the observatory was relocated elsewhere in stages in the first half of the 20th century, and the Greenwich site is now maintained almost exclusively as a museum, although the
AMAT telescope became operational for astronomical research in 2018.
1818 Oversight of the Royal Observatory was transferred from the
Board of Ordnance to the Board of Admiralty; at that time the observatory was charged with maintaining the Royal Navy's
marine chronometers.
1833 Daily time signals began, marked by dropping a
time ball.
1957 Royal Observatory completed its move to Herstmonceux, becoming the Royal Greenwich Observatory (RGO). The Greenwich site was renamed the Old Royal Observatory.
1984 The
IERS Reference Meridian replaces the Greenwich Meridian as the Prime Meridian for the world. Its location is closely related to its predecessor, but runs approximately 102 metres east of it.
1998 RGO closed. Greenwich site was returned to its original name, the Royal Observatory, Greenwich, and was made part of the
National Maritime Museum.
2011 The Greenwich museums, including the ROG, became collectively the Royal Museums Greenwich.
Site
There had been significant buildings on this land since the reign of William I.[8][page needed]Greenwich Palace, on the site of the present-day National Maritime Museum, was the birthplace of both
Henry VIII and his daughters
Mary I and
Elizabeth I;
the Tudors used
Greenwich Castle, which stood on the hilltop that the Observatory presently occupies, as a hunting lodge. Greenwich Castle was reportedly a favourite place for Henry VIII to house his mistresses, so that he could easily travel from the Palace to see them.[9][page needed]
In 1676 the main building of the observatory, now known as Flamsteed House, was completed on Greenwich hill.[10]
Establishment
The establishment of a Royal Observatory was proposed in 1674 by Sir
Jonas Moore who, in his role as
Surveyor-General of the Ordnance, persuaded King Charles II to create the observatory, with John Flamsteed installed as its director.[11] The Ordnance Office was given responsibility for building the Observatory, with Moore providing the key instruments and equipment for the observatory at his own personal cost. Flamsteed House, the original part of the Observatory, was designed by Sir
Christopher Wren, probably assisted by
Robert Hooke, and was the first purpose-built scientific research facility in Britain. It was built for a cost of £520 (£20 over budget; equivalent to £99,000 in 2023) out of largely recycled materials on the foundations of
Duke Humphrey's Tower, the forerunner of Greenwich Castle, which resulted in the alignment being 13 degrees away from true North, somewhat to Flamsteed's chagrin.[citation needed]
Moore donated two clocks, built by
Thomas Tompion, which were installed in the 20 foot high Octagon Room, the principal room of the building. They were of unusual design, each with a pendulum 13 feet (4.0 metres) in length mounted above the clock face, giving a period of four seconds and an accuracy, then unparalleled, of seven seconds per day.
The original observatory housed the astronomer royal, his assistant and his family as well as the scientific instruments to be used by Flamsteed in his work on stellar tables. Over time the institution became a more established institution, thanks to its links to long-lasting government boards (the
Board of Ordnance and
Board of Longitude) and oversight by a Board of Visitors, founded in 1710 and made up of the President and Members of the council of the Royal Society.[12] By the later 18th century it incorporated additional responsibilities such as publishing the Nautical Almanac, advising government on technical matters, disseminating time, making meteorological and magnetic observations and undertaking astrophotography and spectroscopy. The physical site[13] and the numbers of staff[14] increased over time as a result.
Positional astronomy and star charts
When the observatory was founded in 1675, one of the best star catalogues was
Tycho Brahe's 1000-star catalogue from 1598.[15] However, this catalogue was not accurate enough to determine longitudes.[15] One of Flamsteed's first orders of business was creating more accurate charts suitable for this purpose.[15]
One of the noted charts made at Greenwich was by the Astronomer Royal
James Bradley, who between 1750 and 1762 charted sixty thousand stars, so accurately his catalogues were used even in the 1940s.[15] Bradley was the third
Astronomer Royal, and his tenure started in 1742.[16]
In the early 19th century, the main positional devices were the Troughton Transit instrument and a
mural circle, but after
George Biddell Airy took over as Astronomer Royal in 1835, he embarked on a plan to have better instruments at Greenwich observatory.[17]
Positional astronomy was one of the primary functions of Greenwich for the Admiralty.[18] The Astronomer Royal Airy was an advocate of this and the transit circle instrument he had installed in 1851 was used for a century for positional astronomy.[18] One of the difficulties with positional astronomy, is accounting for the
refraction of light through Earth's atmosphere.[19] Sources of error include the precision of the instrumentation, and then there has to be accounting for
precession,
nutation, and
aberration.[20] Sources of error in the instrument have to be tracked down and accounted for to produce more accurate results.[17]
The transit circle makes two measurements; along with a clock, the time a star passed a certain point in the sky as the
Earth rotates, and the vertical angle of the location of the star.[21] The instrument can be used to plot the locations of stars, or alternately, with an accurate star chart, the time at the location of the instrument.[21]
1832 transit of Mercury
The
Shuckburgh telescope of the Royal Observatory in Greenwich was used for the 1832
transit of Mercury.[22] It was equipped with a
filar micrometer by
Peter Dollond and was used to provide a report of the events as seen through the small refractor.[22] By observing the transit in combination with timing it and taking measures, a diameter for the planet was taken.[22] They also reported the peculiar effects that they compared to pressing a coin into the Sun.[22] The observer remarked:
I afterwards observed, that immediately around the planet there was a dusky tinge, making it appear as if, in a small degree sunk below the sun's surface;"
British astronomers have long used the Royal Observatory as a basis for measurement. Four separate
meridians have passed through the buildings, defined by successive instruments.[23] The basis of
longitude, the meridian that passes through the
Airytransit circle, first used in 1851, was adopted as the world's
Prime Meridian at the
International Meridian Conference at
Washington, DC, on 22 October 1884 (voting took place on 13 October).[6] Subsequently, nations across the world used it as their standard for mapping and timekeeping. The Prime Meridian was marked by a brass (later replaced by
stainless steel) strip in the Observatory's courtyard once the buildings became a museum in 1960, and, since 16 December 1999, has been marked by a powerful green
laser shining north across the London night sky.
Since the
first triangulation of Great Britain in the period 1783–1853,
Ordnance Survey maps have been based on an earlier version of the Greenwich meridian, defined by the transit instrument of
James Bradley. When the Airy circle (5.79 m to the east) became the reference for the meridian, the difference resulting from the change was considered small enough to be neglected. When a
new triangulation was done between 1936 and 1962, scientists determined that in the Ordnance Survey system the longitude of the international Greenwich meridian was not 0° but 0°00'00.417" (about 8 m) east.[24] Besides the change of the reference line, imperfections of the surveying system added another discrepancy to the definition of the origin, so that the Bradley line itself is now 0°00'00.12" east of the
Ordnance Survey Zero Meridian (about 2.3 m).[25]
This old astronomical prime meridian has been replaced by a more precise prime meridian. When Greenwich was an active observatory, geographical coordinates were referred to a local
oblate spheroid called a
datum known as a geoid, whose surface closely matched local mean sea level. Several datums were in use around the world, all using different spheroids, because mean sea level undulates by as much as 100 metres worldwide. Modern geodetic reference systems, such as the
World Geodetic System and the
International Terrestrial Reference Frame, use a single oblate spheroid, fixed to the Earth's gravitational centre. The shift from several local spheroids to one worldwide spheroid caused all geographical coordinates to shift by many metres, sometimes as much as several hundred metres. The Prime Meridian of these modern reference systems is the
IERS Reference Meridian, in full the International Earth Rotation and Reference Systems Service Reference Meridian (in short called the IRM), which is 102.5 metres east of the Airy Greenwich astronomical meridian represented by the stainless steel strip, which is now 5.31
arcseconds west. The modern location of the Airy Transit is 51°28′40.1″N0°0′5.3″W / 51.477806°N 0.001472°W / 51.477806; -0.001472 (Airy Transit) as the IRM is at 0 degree in longitude nowadays.[26]
A key instrument for determining time was the Airy Transit Circle (ATC), which was used primarily from 1851 to 1938.[21] It was agreed that the (Prime) "meridian line marked by the cross-hairs in the Airy Transit Circle eyepiece would indicate 0° longitude and the start of the Universal Day". (Note, however, that this Prime Meridian is obsolete; the
ITRF Zero Meridian, which is more than 100 meters east, is the modern standard defining longitude.) The time was determined by marking the time a star of known location would pass through the aimpoint of the telescope.[21] In a reverse case, this type of instrument was also used for making star charts.[21] The stars whose position was known precisely enough for being used for time determination, were called "clock stars".[21]
By 1925, confusion about whether GMT was reckoned from noon or from midnight led (in 1928) to the IAU retiring GMT for astronomical and chronological purposes, replacing it with
Universal Time (UT).[28] In 1929, UT was redefined as a statistical combination of multiple observatories.[29] In 1948, the Office of the Astronomer Royal was moved to Herstmonceux in East Sussex and in 1957, the observatory closed, ceasing time measurement operations.
The term "GMT" continues to be promoted by the Observatory and the UK in general, despite no longer being measured in any way.
Coordinated Universal Time (UTC) forms the basis of modern civil time, and is based on the best attributes of UT1 (the modern form of UT, now measured from extra-galactic radio sources) and
International Atomic Time (TAI, time kept by accurate clocks).
Greenwich Time Ball
The red
time ball of Greenwich was established in 1833, and is noted as a public time signal.[30] The time ball in modern times is normally in a lowered position, then starting at 12:55pm, the ball begins to rise, then at 12:58 it reaches the top; at 1pm the ball drops.[30]
To help mariners at the port and others in line of sight of the observatory to synchronise their clocks to GMT, Astronomer Royal
John Pond installed a very visible time ball that drops precisely at 1pm (13:00) every day atop the observatory in 1833. Initially it was dropped by an operator; from 1852 it was released automatically via an electric impulse from the
Shepherd Master Clock.[31] The ball is still dropped daily at 13:00 (GMT in winter,
BST in summer).[32]
The original time ball system was built by Messrs Maudslay and Field, and cost £180.[33] The five-foot diameter ball was made of wood and leather.[33] In the original ball system, it was hoisted by a rope up from the Octagon room, and there was a catch at the top to hold it.[33] This could then be triggered by hand, while observing the time on an astronomical month clock, that was regulated to the
mean solar time.[33]
By dropping the ball, the public, mariners, and clock makers could then get a time signal by viewing it from afar.[33] The ball drop would be repeated at 2pm also if possible.[33]
The reason why 12 noon was not chosen was because astronomers at the observatory would record when the Sun crossed the meridian at that time on that day.[34]
In rare occasions where the ball could get stuck due to icing or snow, and if the wind was too high it would not be dropped.[33][35] In 1852, it was established to distribute a time signal by the telegraph wires also.[33]
The time ball was extremely popular with the public, chronometers, railways, mariners, and there was a petition to have another time ball established in
Southampton also.[33]
1890s
The 1890s marked the addition of a new larger refractor, the 28-inch Grubb in the Great Equatorial Dome. Because the new telescope was longer than the old Great refractor, the new dome had to be bigger; thus the famous "onion dome" that expands beyond the diameter of the turret was established. For the tricentennial, it was revitalized with a
fibre-glass dome; the old one made of
papier-mâché and iron had been taken down.
The
Lassell two-foot reflector was a famous metal-mirror telescope that had been used to discover the Moons
Triton (orbiting Neptune) and
Hyperion (orbiting Saturn).[37] It was donated to the observatory in the 1880s, but was taken down in the 1890s.[37]
The 1890s also saw the construction of the Altazimuth Pavilion, completed in 1896 and designed by William Crisp.[38]
In 1898 the Christie Enclosure was established to house sensitive magnetic instruments that had been disrupted by the use of iron at the main facility.[39]
The Observatory underwent an attempted bombing on 15 February 1894. This was possibly the first "international terrorist" incident in Britain.[40] The bomb was accidentally detonated while being held by 26-year-old French
anarchistMartial Bourdin in
Greenwich Park, near the Observatory building. Bourdin died about 30 minutes later. It is not known why he chose the observatory, or whether the detonation was intended to occur elsewhere. The novelist
Joseph Conrad used the incident in his 1907 novel The Secret Agent.[41]
Early 20th century
For major parts of the twentieth century, the Royal Greenwich Observatory was not at Greenwich, because it moved to
Herstmonceux in East Sussex in 1957. The last time that all departments were in Greenwich was 1924: in that year electrification of the railways affected the readings of the
Magnetic and
Meteorological Departments, and the Magnetic Observatory moved to
Abinger in Surrey. Prior to this, the observatory had had to insist that the electric trams in the vicinity could not use an earth return for the traction current.[42]
After the onset of
World War II in 1939, many departments were temporarily evacuated out of range of German bombers, to Abinger,
Bradford on Avon,
Bristol,[43] and
Bath,[44] and activities in Greenwich were reduced to the bare minimum.
On 15 October 1940, during
the Blitz, the Courtyard gates were destroyed by a direct bomb hit. The wall above the Gate Clock collapsed, and the clock's dial was damaged. The damage was repaired after the war.[45]
The Royal Observatory at Herstmonceux
After the Second World War, in 1947, the decision was made to move the Royal Observatory to
Herstmonceux Castle[46] and 320 adjacent acres (1.3 km2), 70 km south-southeast of Greenwich near
Hailsham in East Sussex, due to
light pollution in London. The Observatory was officially known as the Royal Greenwich Observatory, Herstmonceux. Although the
Astronomer RoyalHarold Spencer Jones moved to the castle in 1948, the scientific staff did not move until the observatory buildings were completed, in 1957. Shortly thereafter, other previously dispersed departments were reintegrated at Herstmonceux, such as the
Nautical Almanac Office, Chronometer Department, the library, and observing equipment.[47]
The largest telescope at Greenwich at that time, the
Yapp telescope 36-inch reflector, was moved out to Herstmonceux in 1958.[48] There it was reconstructed in Dome B of the facility.[48] There it was used for astronomy in the 1960s, 1970s, and 1980s. It was left behind at Herstmonceux in 1990 in its dome when the organization moved once again.[47]
The tricentennial of
Sir Isaac Newton had passed during the Second World War, delaying festivities. One of the ground-swells was to build a 'big better' telescope in honour of the celebrated inventor of the Newtonian reflecting telescope. Some two decades of development led to the commissioning of the Isaac Newton Telescope at Herstmonceux. It proved so successful that the cloudy weather was felt to be a bottleneck to its productivity, and plans were made to get it to a higher spot with better weather.
On 1 December 1967, the
Isaac Newton Telescope of the Royal Greenwich Observatory at Herstmonceux was inaugurated by Queen Elizabeth II.[49] The telescope was the biggest telescope by aperture in the British Isles.[50] It was moved to
Roque de los Muchachos Observatory in Spain's
Canary Islands in 1979. In 1990 the RGO moved to
Cambridge.[51] At Herstmonceux, the castle grounds became the home of the International Study Centre of
Queen's University, Kingston, Canada, and The Observatory Science Centre,[52] which is operated by an educational charity Science Project.
The Observatory Science Centre opened in April 1995.[53] Some of the remaining telescopes, which were left behind in the move, have public observation events as part of operations of the centre.[53] The centre has established itself as a noted tourist and education attraction in its own right, featuring many old observatory items as exhibits.[54] It was getting 60,000 visitors per year in the early 21st century.[53]
The Astronomer Royal
Martin Rees called PPARC "irresponsible" for how it handled the RGO.[56]
Greenwich site returns to active use
In 2018 the
Annie Maunder Astrographic Telescope (AMAT) was installed at the ROG in Greenwich.[57][58] AMAT is a cluster of four separate instruments, to be used for astronomical research; it had achieved
first light by June 2018, and contains:[59]
A 14-inch reflector that can take high-resolution images of the sun, moon and planets.
An instrument dedicated to observing the sun.
An instrument with interchangeable filters to view distant
nebulae at different optical wavelengths.
A general-purpose telescope.
The telescopes and the works at the site required to operate them cost about £150,000, from grants, museum members and patrons, and public donations.
The telescope was installed in the Altazimuth Pavilion,[60] from which the multi-purpose telescope is controlled by a computer system.[60]
Magnetic observations
The first magnetic observation was taken in 1680 by the first Astronomer Royal, John Flamsteed, using a magnetic needle from the Royal Society.[61] The second and third Astronomers Royal,
Edmond Halley and then James Bradley, also took some magnetic measurements during their tenure.[61]
In the 19th century George Airy established the Magnetical and Meteorological Department.[61]
The first Magnetic House was built next to the observatory but by 1900 a second, about 300–400 metres from the main observatory, was built to reduce magnetic interference.[62] Both houses were made of non-magnetic materials.[62] The older building was called the Magnet House, but iron added to buildings in the 1890s at the observatory was throwing off measurements, so the instruments were moved to the Magnetic Pavilion.[62] A new Magnetograph House was also completed by 1914.[62]
The observatory buildings at Greenwich became a museum of astronomical and navigational tools, which is part of the Royal Museums Greenwich.[64] Notable exhibits include
John Harrison's pioneering
chronometer, known as
H4, for which he received a large reward from the
Board of Longitude, and his three earlier marine timekeepers; all four are the property of the
Ministry of Defence. Many additional horological artefacts are displayed, documenting the history of precision timekeeping for navigational and astronomical purposes, including the mid-20th-century Russian-made F.M. Fedchenko clock (the most accurate pendulum clock ever built in multiple copies). It also houses the astronomical instruments used to make meridian observations and the 28-inch equatorial
Grubbrefracting telescope of 1893, the largest of its kind in the UK. The
Shepherd Clock outside the observatory gate is an early example of an
electric slave clock.
In 1997 the observatory site was getting 400,000 visitors per year.[65]
In February 2005 a £16 million redevelopment comprising a new
planetarium and additional display galleries and educational facilities was started; the ROG reopened on 25 May 2007 with the new 120-seat
Peter Harrison Planetarium.[66]
For a year between 2016 and 2017 the Museum reported 2.41 million visitors.[67]
The
Queen's House (centre left) at Greenwich, with the Royal Observatory on the skyline behind (2017)
Imperial standard lengths on the wall of the Royal Observatory, Greenwich, London – 1 yard (3 feet), 2 feet, 1 foot, 6 inches (1/2-foot), and 3 inches. The separation of the inside faces of the marks is exact at an ambient temperature of 60 °F (16 °C) and a rod of the correct measure, resting on the pins, will fit snugly between them.[68][69]
^Seago, John H.; Seidelmann, P. Kenneth.
"The mean-solar-time origin of Universal Time and UTC"(PDF). Paper presented at the AAS/AIAA Spaceflight Mechanics Meeting, Kauai, HI, USA, March 2013. Reprinted from Advances in the Astronomical Sciences v. 148. pp. 1789, 1801, 1805. Archived from
the original(PDF) on 27 December 2013.
^Matusitz, Jonathan Andre (16 September 2014). Symbolism in terrorism : motivation, communication, and behavior. Lanham: Rowman & Littlefield.
ISBN9781442235793.
OCLC891148726.
^Bennett, Keith (2004), Bucher, Jay L. (ed.), The Metrology Handbook, Milwaukee, WI: American Society for Quality Measurement, p. 8,
ISBN978-0-87389-620-7.
Greenwich Observatory: ... the Royal Observatory at Greenwich and Herstmonceux, 1675–1975. London: Taylor & Francis, 1975 3v. (Vol. 1. Origins and early history (1675–1835), by Eric G. Forbes.
ISBN0-85066-093-9; Vol. 2. Recent history (1836–1975), by A.J. Meadows.
ISBN0-85066-094-7; Vol. 3. The buildings and instruments by Derek Howse.
ISBN0-85066-095-5)