History of sundials

Last updated October 08, 2024

World's oldest known sundial, from Egypt's Valley of the Kings (c. 1500 BC), used to measure work hours. Ancient-egyptian-sundial.jpg — World's oldest known sundial, from Egypt's Valley of the Kings (c. 1500 BC), used to measure work hours.

A sundial is a device that indicates time by using a light spot or shadow cast by the position of the Sun on a reference scale.^[4] As the Earth turns on its polar axis, the sun appears to cross the sky from east to west, rising at sun-rise from beneath the horizon to a zenith at mid-day and falling again behind the horizon at sunset. Both the azimuth (direction) and the altitude (height) can be used to create time measuring devices. Sundials have been invented independently in every major culture and became more accurate and sophisticated as the culture developed. ^[5]

Introduction

A sundial uses local time. Before the coming of the railways in the 1840s, local time was displayed on a sundial and was used by the government and commerce. Before the invention of the clock the sundial was the only way to measure time. After the invention of the clock, the sundial maintained its importance, as clocks needed to be reset regularly from a sundial, because the accuracy of early clocks was poor. A clock and a sundial were used together to measure longitude. Dials were laid out using straightedges and compasses. In the late nineteenth century sundials became objects of academic interest. The use of logarithms allowed algebraic methods of laying out dials to be employed and studied. No longer utilitarian, sundials remained as popular ornaments, and several popular books promoted that interest and gave constructional details. Affordable scientific calculators made the algebraic methods as accessible as the geometric constructions and the use of computers made dial plate design trivial. The heritage of sundials was recognised and sundial societies were set up worldwide, and certain legislations made studying sundials part of their national school curriculums. ^[5]

History

Ancient sundials

Hemispherical Greek sundial from Ai Khanoum, Afghanistan (3rd-2nd century BCE). SunDialAiKhanoum.jpg — Hemispherical Greek sundial from Ai Khanoum, Afghanistan (3rd–2nd century BCE).

The earliest household clocks known, from the archaeological finds, are the sundials (1500 BCE) in Ancient Egypt and ancient Babylonian astronomy. Ancient analemmatic sundials of the same era (about 1500 BCE) and their prototype have been discovered on the territory of modern Russia.^[6]^[7]^[8]^[9] Much earlier obelisks, once thought to have been used also as sundials, placed at temples built in honor of a pharaoh, are now thought to serve only as a memorial.^[10] Presumably, humans were telling time from shadow-lengths at an even earlier date, but this is hard to verify. In roughly 700 BCE, the Old Testament describes a sundial – the "dial of Ahaz" mentioned in Isaiah 38:8 and 2 Kings 20:9 (possibly the earliest account of a sundial that is anywhere to be found in history)—which was likely of Egyptian or Babylonian design. Sundials were also developed in Kush.^[11]^[12] Sundials existed in China since ancient times, but very little is known of their history. It is known that the ancient Chinese developed a form of sundials c. 800 BCE, and the sundials eventually evolved to very sophisticated water clocks by 1000 CE, and sometime in the Song dynasty (1000–1400 CE), a compass would sometimes also be constructed on the sundial.^[13]

An early reference to sundials from 104 BCE is in an assembly of calendar experts.^[14]

The ancient Greeks developed many of the principles and forms of the sundial. Sundials are believed to have been introduced into Greece by Anaximander of Miletus, c. 560 BCE. According to Herodotus, Greek sundials were initially derived from their Babylonian counterparts. The Greeks were well-positioned to develop the science of sundials, having developed the science of geometry, and in particular discovering the conic sections that are traced by a sundial nodus. The mathematician and astronomer Theodosius of Bithynia (c. 160 BCE to c. 100 BCE) is said to have invented a universal sundial that could be used anywhere on Earth.^[15]

The Romans adopted the Greek sundials, and the first record of a sundial in Rome is in 293 BCE according to Pliny.^[16] A comic character in a play by Plautus complained about his day being "chopped into pieces" by the ubiquitous sundials. Writing in c. 25 BCE, the Roman author Vitruvius listed all the known types of dials in Book IX of his De Architectura , together with their Greek inventors.^[17] All of these are believed to be nodus-type sundials, differing mainly in the surface that receives the shadow of the nodus.^{[ citation needed ]}

the hemicyclium of Berosus the Chaldean: a truncated, concave, hemispherical surface
the hemispherium or scaphe of Aristarchus of Samos: a full, concave, hemispherical surface
the discus (a disc on a plane surface) of Aristarchus of Samos: a fully circular equatorial dial with nodus
the arachne (spiderweb) of Eudoxus of Cnidus or Apollonius of Perga: half a circular equatorial dial with nodus
the plinthium or lacunar of Scopinas of Syracuse: an example in the Circus Flaminius)
the pros ta historoumena (universal dial) of Parmenio
the pros pan klima of Theodosius of Bithynia and Andreas
the pelekinon of Patrocles: the classic double-bladed axe design of hyperbolae on a planar surface
the cone of Dionysodorus: a concave, conical surface
the quiver of Apollonius of Perga
the conarachne
the conical plinthium
the antiboreum: a hemispherium that faces North, with the sunlight entering through a small hole.

The Romans built a very large sundial in c. 10 BCE, the Solarium Augusti, which is a classic nodus-based obelisk casting a shadow on a planar pelekinon.^[18] The Globe of Matelica is felt to have been part of an Ancient Roman sundial from the 1st or 2nd century.^{[ citation needed ]}

The custom of measuring time by one's shadow has persisted since ancient times. In Aristophanes' play Assembly of Women, Praxagora asks her husband to return when his shadow reaches 10 feet (3.0 m).

Medieval sundials

The Greek dials were inherited and developed further by astronomers of the Islamic Caliphates and post-Renaissance Europeans.

The Venerable Bede is reported to have instructed his followers in the art of telling time by interpreting their shadow lengths, however, Bede's most important association with sundials is that he encouraged the use of canonical sundials to fix the times of prayers.^{[ citation needed ]} The oldest sundial in England is a tide dial incorporated into the Bewcastle Cross, Cumbria, and dates from the 7th or early 8th century.^[19]

Since the Greek dials were nodus-based with straight hour-lines, they indicated unequal hours that varied with the seasons, since every day was divided into twelve equal segments; hours were shorter in winter and longer in summer. Sundials with gnomons oriented towards the celestial pole are able to exploit the fact that the markings for the equinoctial hours are a family of straight-line segments, thereby allowing for the measure of equal hours. It is unclear when such sundials were first built. A polar-axis sundial was constructed by the 14th century Arabic engineer Ibn al-Shatir, a replica of which still exists today, though he was not the inventor of the device. The concept may have been known for centuries before his time, and appeared in Western sundials from at least 1446.^[20]^[21]^[5]

Europe then saw an explosion of new designs. Italian astronomer Giovanni Padovani published a treatise on the sundial in 1570, in which he included instructions for the manufacture and laying out of mural (vertical) and horizontal sundials. Giuseppe Biancani's Constructio instrumenti ad horologia solaria (ca. 1620) discusses how to make a perfect sundial, with accompanying illustrations.^{[ citation needed ]}

The villages around Briançon, Hautes-Alpes, France were a major site of sundial production in the 18th and 19th centuries, with at least 400 painted dials in this one French department. Among the most famous sundial makers of this era was Giovanni Francesco Zarbula, who created a hundred of them between 1833 and 1881.^[22]

Modern dialing

Designers of the Taipei 101, the first record-setting skyscraper of the 21st century, brought the ancient tradition forward. The tower, tallest in the world when it opened in Taiwan in 2004, stands over 500 metres (1,600 ft) in height. The design of an adjoining park uses the tower as the style for a huge horizontal sundial.^{[ citation needed ]}

Gallery

Old sundial located in the Great Mosque of Kairouan also known as the Mosque of Uqba, in Kairouan, Tunisia.
A Scottish gravestone bearing a sundial. The instrument has often doubled as a memento mori.
A medieval mass dial (minus its gnomon) at St. Mary, Bibury; also known as a scratch dial, it was used to tell the times of Mass.
This sundial displays a likeness of Father Time. Its motto quotes Robert Browning: "Grow old along with me; the best is yet to be."
Marble equatorial sundial in the Europapark of Klagenfurt on Lake Woerth, Carinthia, Austria
The Giant Sundial of Jantar Mantar in Jaipur, India, stands 27m tall. Its shadow moves visibly at 1 mm per second. 26°55′29″N75°49′29″E / 26.9247°N 75.8248°E / 26.9247; 75.8248
Several sundials arrayed on the faces of a cube. The styles are all parallel and meant to be aligned with the Earth's rotation axis.

Modern

Martin Bernhardt created a special gnomon for an equatorial sundial which adjusts for the equation of time and that allows one to read the time without knowing the date, to a precision of less than a minute.
A modern hemispherium in Gyeongbok Palace in Seoul, South Korea. 37°34′43″N126°58′38″E / 37.578611°N 126.977222°E / 37.578611; 126.977222 (Gyeongbok Palace hemispherium) The pointer tip acts as the nodus; the height of the nodus-shadow gives the time of the year.
High precision (±30 seconds) sundial in Belgium (Google Earth)

Related Research Articles

<span class="mw-page-title-main">Sundial</span> Device that tells the time of day by the apparent position of the Sun in the sky

A sundial is a horological device that tells the time of day when direct sunlight shines by the apparent position of the Sun in the sky. In the narrowest sense of the word, it consists of a flat plate and a gnomon, which casts a shadow onto the dial. As the Sun appears to move through the sky, the shadow aligns with different hour-lines, which are marked on the dial to indicate the time of day. The style is the time-telling edge of the gnomon, though a single point or nodus may be used. The gnomon casts a broad shadow; the shadow of the style shows the time. The gnomon may be a rod, wire, or elaborately decorated metal casting. The style must be parallel to the axis of the Earth's rotation for the sundial to be accurate throughout the year. The style's angle from horizontal is equal to the sundial's geographical latitude.

A diptych is any object with two flat plates which form a pair, often attached by a hinge. For example, the standard notebook and school exercise book of the ancient world was a diptych consisting of a pair of such plates that contained a recessed space filled with wax. Writing was accomplished by scratching the wax surface with a stylus. When the notes were no longer needed, the wax could be slightly heated and then smoothed to allow reuse. Ordinary versions had wooden frames, but more luxurious diptychs were crafted with more expensive materials.

A gnomon is the part of a sundial that casts a shadow. The term is used for a variety of purposes in mathematics and other fields.

Solar time is a calculation of the passage of time based on the position of the Sun in the sky. The fundamental unit of solar time is the day, based on the synodic rotation period. Traditionally, there are three types of time reckoning based on astronomical observations: apparent solar time and mean solar time, and sidereal time, which is based on the apparent motions of stars other than the Sun.

The scaphe was a sundial said to have been invented by Aristarchus of Samos. There are no original works still in existence by Aristarchus, but the adjacent picture is an image of what it might have looked like; only his would have been made of stone. It consisted of a hemispherical bowl which had a vertical gnomon placed inside it, with the top of the gnomon level with the edge of the bowl. Twelve gradations inscribed perpendicular to the hemisphere indicated the hour of the day.

The MarsDial is a sundial that was devised for missions to Mars. It is used to calibrate the Pancam cameras of the Mars landers. MarsDials were placed on the Spirit and Opportunity Mars rovers, inscribed with the words "Two worlds, One sun" and the word "Mars" in 22 languages. The MarsDial can function as a gnomon, the stick or other vertical part of a sundial. The length and direction of the shadow cast by the stick allows observers to calculate the time of day. The sundial can also be used to tell which way is North, and to overcome the limitations of a magnetic north different from a true north.

The Jantar Mantar is a collection of 19 astronomical instruments built by the Rajput king Sawai Jai Singh, the founder of Jaipur, Rajasthan. The monument was completed in 1734. It features the world's largest stone sundial, and is a UNESCO World Heritage Site. It is near City Palace and Hawa Mahal. The instruments allow the observation of astronomical positions with the naked eye. The observatory is an example of the Ptolemaic positional astronomy which was shared by many civilizations.

<span class="mw-page-title-main">Analemmatic sundial</span>

Analemmatic sundials are a type of horizontal sundial that has a vertical gnomon and hour markers positioned in an elliptical pattern. The gnomon is not fixed and must change position daily to accurately indicate time of day. Hence there are no hour lines on the dial and the time of day is read only on the ellipse. As with most sundials, analemmatic sundials mark solar time rather than clock time.

Man Enters the Cosmos is a cast bronze sculpture by Henry Moore located on the Lake Michigan lakefront outside the Adler Planetarium in the Museum Campus area of downtown Chicago, Illinois.

The Solarium Augusti or Horologium Augusti was a monument in the Campus Martius of ancient Rome constructed in 10 BCE under the Roman emperor Augustus. It included an Egyptian obelisk that had first been erected under the pharaoh Psamtik II used in some fashion as a gnomon. Once believed to have been a massive sundial, it is now more commonly understood to have been used with a meridian line used to track the solar year. It served as a monument of Augustus having brought Egypt under Roman rule and was also connected with the Altar of Augustan Peace commemorating the Pax Romana established by his ending the numerous civil wars that ended the Roman Republic. The Solarium was destroyed at some point during the Middle Ages. Its recovered obelisk is now known as the Obelisk of Montecitorio.

<span class="mw-page-title-main">History of timekeeping devices in Egypt</span>

The ancient Egyptians were one of the first cultures to widely divide days into generally agreed-upon equal parts, using early timekeeping devices such as sundials, shadow clocks, and merkhets . Obelisks were also used by reading the shadow that they make. The clock was split into daytime and nighttime, and then into smaller hours.

Astronomical rings, also known as Gemma's rings, are an early astronomical instrument. The instrument consists of three rings, representing the celestial equator, declination, and the meridian.

Shadows is a software package for the calculation and drawing of sundials and astrolabes, available as a freeware in its base level.

The Whitehurst & Son sundial was produced in Derby in 1812 by the nephew of John Whitehurst. It is a fine example of a precision sundial telling local apparent time with a scale to convert this to local mean time, and is accurate to the nearest minute. The sundial is now housed in the Derby Museum and Art Gallery.

<span class="mw-page-title-main">Noon mark</span>

The Noon mark is a type of sundial that at its simplest is a vertical line on a south facing wall or a north-south line on a horizontal pavement. When the shadow of a point crosses the line it will be midday. Noon in local standard time is defined as when the sun is overhead, however clocks and watches use mean time which varies from standard time by a few minutes each day. The difference is calculated using the equation of time and this can be shown on the noon mark by drawing an analemma, or using a correction table.

<span class="mw-page-title-main">Bifilar sundial</span>

A bifilar dial is a type of sundial invented by the German mathematician Hugo Michnik in 1922. It has two non-touching threads parallel to the dial. Usually the second thread is orthogonal-(perpendicular) to the first. The intersection of the two threads' shadows gives the local apparent time.

A tide dial, also known as a mass dial or a scratch dial, is a sundial marked with the canonical hours rather than or in addition to the standard hours of daylight. Such sundials were particularly common between the 7th and 14th centuries in Europe, at which point they began to be replaced by mechanical clocks. There are more than 3,000 surviving tide dials in England and at least 1,500 in France.

The Sundial in Taganrog was set in 1833. It is situated in Grecheskaya Street, close to the Depaldo Stairs. It is officially declared an object of cultural heritage of Russia of Regional significance.

This timeline of time measurement inventions is a chronological list of particularly important or significant technological inventions relating to timekeeping devices and their inventors, where known.

References

↑ "Preliminary Report on the Work carried out during the season 2013". Archived from the original on 2016-12-28. Retrieved 2016-12-28.
↑ Bickel, S.; Gautschy, R. Eine ramessidische Sonnenuhr im Tal der Könige. Zeitschrift für Ägyptische Sprache und Altertumskunde 2014, Volume 96, Issue 1, pp. 3–14.
↑ Vodolazhskaya, L.N. Reconstruction of ancient Egyptian sundials. Archaeoastronomy and Ancient Technologies 2014, 2(2), 1–18.
↑ Jones 2005, p. 1.
1 2 3 Jones 2005.
↑ Vodolazhskaya, L.N.; Larenok, P.A.; Nevsky, M.Yu.The ancient astronomical instrument from Srubna burial of kurgan field Tavriya-1 (Northern Black Sea Coast). Archaeologist and Ancient Technologies 2014, 2(2), 31–53.
↑ Vodolazhskaya, L.N. Analemmatic and horizontal sundials of the Bronze Age (Northern Black Sea Coast). Archaeoastronomy and Ancient Technologies 2013, 1(1), 68–88.
↑ Vodolazhskaya L.N., Larenok P.A., Nevsky M.Yu. The prototype of ancient analemmatic sundials (Rostov Oblast, Russia). Archaeoastronomy and Ancient Technologies 2016, 4(1), 96–116.
↑ Vodolazhskaya, L.N.; Larenok, P.A.; Nevsky, M.Yu. Solnechnye chasy epokhi bronzy is srubnogo pogrebeniya mogil'nika Tavriya-1. [Sundial of Bronze Age from the Srubna burial of kurgan field Tavriya-1]. Istoriko-arkheologicheskiy al'manakh. [Historical-Archaeological Almanac]. Vol. 13, Armavir, Krasnodar, Moscow, 2015, p. 4-14.
↑ "The oldest surviving sundial". Archived from the original on 2021-04-11. Retrieved 2013-01-11.
↑ Depuydt, Leo (1 January 1998). "Gnomons at Meroë and Early Trigonometry". The Journal of Egyptian Archaeology. 84: 171–180. doi:10.2307/3822211. JSTOR 3822211.
↑ Slayman, Andrew (27 May 1998). "Neolithic Skywatchers". Archaeology Magazine Archive. Archived from the original on 5 June 2011. Retrieved 17 April 2011.
↑ "Sundials in China – A brief note". The University of Hong Kong. 1997-07-01. Archived from the original on 2010-03-14. Retrieved 2010-01-20.
↑ Joseph Needham (1959). Science and Civilisation in China. Vol. 3. C.U.P. p. 302.
↑ Heath 1911, p. 771.
↑ Pliny (79ce): Natural History 7.213
↑ "Marcus Vitruvius Pollio:de Architectura, Book IX". The Latin text is that of the Teubner edition of 1899 by Valentin Rose, transcribed by Bill Thayer. 2007-07-07. Retrieved 2007-09-07.
↑ Edmund Buchner, "Solarium Augusti und Ara Pacis", Römische Mitteilungen83 (1976:319-75); Die Sonnenuhr des Augustus: Kaiser Augustus und die verlorene Republik (Berlin) 1988.
↑ Ó Carragaáin, Éamonn, Christian Inculturation in Eighth-Century Northumbria: The Bewcastle and Ruthwell Crosses, Colloquium Magazine, Vol 4, Autumn 2007, Yale Institute of Sacred Music, online text, with many photographs
↑ King, David (2021). World-maps for Finding the Direction and Distance to Mecca. Brill. p. 298. ISBN 9789004450738.
↑ "History of the sundial". National Maritime Museum. Archived from the original on 2007-10-10. Retrieved 2008-07-02.
↑ Savoie, Dennis (2022). Anthony Turner; James Nye; Jonathan Betts (eds.). A General History of Horology. Oxford University Press. p. 250. ISBN 9780192609366.

Bibliography

Earle AM (1971). Sundials and Roses of Yesterday . Rutland, VT: Charles E. Tuttle. ISBN 0-8048-0968-2. LCCN 74142763. Reprint of the 1902 book published by Macmillan (New York).
Heath, Thomas Little (1911). "Theodosius of Tripolis" . In Chisholm, Hugh (ed.). Encyclopædia Britannica . Vol. 26 (11th ed.). Cambridge University Press. pp. 771–772.
A. P. Herbert, Sundials Old and New, Methuen & Co. Ltd, 1967.
Jones, Lawrence (December 2005). "The Sundial And Geometry". North American Sundial Society. 12 (4).
Mayall RN, Mayall MW (1994). Sundials: Their Construction and Use (3rd ed.). Cambridge, MA: Sky Publishing. ISBN 0-933346-71-9.
Hugo Michnik, Theorie einer Bifilar-Sonnenuhr, Astronomishe Nachrichten, 217(5190), p. 81-90, 1923
Rohr RRJ (1996). Sundials: History, Theory, and Practice (translated by G. Godin ed.). New York: Dover. ISBN 0-486-29139-1. Slightly amended reprint of the 1970 translation published by University of Toronto Press (Toronto). The original was published in 1965 under the title Les Cadrans solaires by Gauthier-Villars (Montrouge, France).
Frederick W. Sawyer, Bifilar gnomonics, JBAA (Journal of the British Astronomical association), 88(4):334–351, 1978
Gerard L'E. Turner, Antique Scientific Instruments, Blandford Press Ltd. 1980 ISBN 0-7137-1068-3
J.L. Heilbron, The sun in the church: cathedrals as solar observatories, Harvard University Press, 2001 ISBN 978-0-674-00536-5.
Make A Sundial, (The Education Group British Sundial Society) Editors Jane Walker and David Brown, British Sundial Society 1991 ISBN 0-9518404-0-1
Waugh AE (1973). Sundials: Their Theory and Construction . New York: Dover Publications. ISBN 0-486-22947-5.
"Illustrating Shadows", Simon Wheaton-Smith, ISBN 0-9765286-8-1, LCN: 2005900674

External links

British Sundial Society- Time line and register
The Ancient Vedic Sun Dial

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[1] "Preliminary Report on the Work carried out during the season 2013". Archived from the original on 2016-12-28. Retrieved 2016-12-28.

[2] Bickel, S.; Gautschy, R. Eine ramessidische Sonnenuhr im Tal der Könige. Zeitschrift für Ägyptische Sprache und Altertumskunde 2014, Volume 96, Issue 1, pp. 3–14.

[3] Vodolazhskaya, L.N. Reconstruction of ancient Egyptian sundials. Archaeoastronomy and Ancient Technologies 2014, 2(2), 1–18.

[FOOTNOTEJones20051-4] Jones 2005, p. 1.

[FOOTNOTEJones2005-5] 1 2 3 Jones 2005.

[6] Vodolazhskaya, L.N.; Larenok, P.A.; Nevsky, M.Yu.The ancient astronomical instrument from Srubna burial of kurgan field Tavriya-1 (Northern Black Sea Coast). Archaeologist and Ancient Technologies 2014, 2(2), 31–53.

[7] Vodolazhskaya, L.N. Analemmatic and horizontal sundials of the Bronze Age (Northern Black Sea Coast). Archaeoastronomy and Ancient Technologies 2013, 1(1), 68–88.

[8] Vodolazhskaya L.N., Larenok P.A., Nevsky M.Yu. The prototype of ancient analemmatic sundials (Rostov Oblast, Russia). Archaeoastronomy and Ancient Technologies 2016, 4(1), 96–116.

[9] Vodolazhskaya, L.N.; Larenok, P.A.; Nevsky, M.Yu. Solnechnye chasy epokhi bronzy is srubnogo pogrebeniya mogil'nika Tavriya-1. [Sundial of Bronze Age from the Srubna burial of kurgan field Tavriya-1]. Istoriko-arkheologicheskiy al'manakh. [Historical-Archaeological Almanac]. Vol. 13, Armavir, Krasnodar, Moscow, 2015, p. 4-14.

[10] "The oldest surviving sundial". Archived from the original on 2021-04-11. Retrieved 2013-01-11.

[11] Depuydt, Leo (1 January 1998). "Gnomons at Meroë and Early Trigonometry". The Journal of Egyptian Archaeology. 84: 171–180. doi:10.2307/3822211. JSTOR 3822211.

[12] Slayman, Andrew (27 May 1998). "Neolithic Skywatchers". Archaeology Magazine Archive. Archived from the original on 5 June 2011. Retrieved 17 April 2011.

[cheung-13] "Sundials in China – A brief note". The University of Hong Kong. 1997-07-01. Archived from the original on 2010-03-14. Retrieved 2010-01-20.

[14] Joseph Needham (1959). Science and Civilisation in China. Vol. 3. C.U.P. p. 302.

[FOOTNOTEHeath1911771-15] Heath 1911, p. 771.

[16] Pliny (79ce): Natural History 7.213

[thayer-17] "Marcus Vitruvius Pollio:de Architectura, Book IX". The Latin text is that of the Teubner edition of 1899 by Valentin Rose, transcribed by Bill Thayer. 2007-07-07. Retrieved 2007-09-07.

[18] Edmund Buchner, "Solarium Augusti und Ara Pacis", Römische Mitteilungen83 (1976:319-75); Die Sonnenuhr des Augustus: Kaiser Augustus und die verlorene Republik (Berlin) 1988.

[19] Ó Carragaáin, Éamonn, Christian Inculturation in Eighth-Century Northumbria: The Bewcastle and Ruthwell Crosses, Colloquium Magazine, Vol 4, Autumn 2007, Yale Institute of Sacred Music, online text, with many photographs

[20] King, David (2021). World-maps for Finding the Direction and Distance to Mecca. Brill. p. 298. ISBN 9789004450738.

[21] "History of the sundial". National Maritime Museum. Archived from the original on 2007-10-10. Retrieved 2008-07-02.

[22] Savoie, Dennis (2022). Anthony Turner; James Nye; Jonathan Betts (eds.). A General History of Horology. Oxford University Press. p. 250. ISBN 9780192609366.

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v t e Time measurement and standards
Chronometry Orders of magnitude Metrology
International standards	Coordinated Universal Time offset UT ΔT DUT1 International Earth Rotation and Reference Systems Service ISO 31-1 ISO 8601 International Atomic Time 12-hour clock 24-hour clock Barycentric Coordinate Time Barycentric Dynamical Time Civil time Daylight saving time Geocentric Coordinate Time International Date Line IERS Reference Meridian Leap second Solar time Terrestrial Time Time zone 180th meridian
Obsolete standards	Ephemeris time Greenwich Mean Time Prime meridian
Time in physics	Absolute space and time Spacetime Chronon Continuous signal Coordinate time Cosmological decade Discrete time and continuous time Proper time Theory of relativity Time dilation Gravitational time dilation Time domain Time-translation symmetry T-symmetry
Horology	Clock Astrarium Atomic clock Complication History of timekeeping devices Hourglass Marine chronometer Marine sandglass Radio clock Watch stopwatch Water clock Sundial Dialing scales Equation of time History of sundials Sundial markup schema
Calendar	Gregorian Hebrew Hindu Holocene Islamic (lunar Hijri) Julian Solar Hijri Astronomical Dominical letter Epact Equinox Intercalation Julian day Leap year Lunar Lunisolar Solar Solstice Tropical year Weekday determination Weekday names
Archaeology and geology	Chronological dating Geologic time scale International Commission on Stratigraphy
Astronomical chronology	Galactic year Nuclear timescale Precession Sidereal time
Other units of time	Instant Flick Shake Jiffy Second Minute Moment Hour Day Week Fortnight Month Year Olympiad Lustrum Decade Century Saeculum Millennium
Related topics	Chronology Duration music Mental chronometry Decimal time Metric time System time Time metrology Time value of money Timekeeper