Epoch

Reference point from which time is measured

In chronology and periodization, an epoch or reference epoch is an instant in time chosen as the origin of a particular calendar era. The "epoch" serves as a reference point from which time is measured.

The moment of epoch is usually decided by congruity, or by following conventions understood from the epoch in question. The epoch moment or date is usually defined from a specific, clear event of change, an epoch event. In a more gradual change, a deciding moment is chosen when the epoch criterion was reached.

Calendar eras

Pre-modern eras

The Yoruba calendar (Kọ́jọ́dá) uses 8042 BC as the epoch, regarded as the year of the creation of Ile-Ife by the god Obatala, also regarded as the creation of the earth.
Anno Mundi (years since the creation of the world) is used in the Byzantine calendar (5509 BC).
Anno Mundi (years since the creation of the world) as used in the Hebrew calendar (3761 BC).^[1]^[2]
The Mesoamerican Long Count Calendar uses the creation of the fourth world in 3114 BC.
Olympiads, the ancient Greek era of four-year periods between Olympic Games, beginning in 776 BC.
Ab urbe condita ("from the foundation of the city"), used to some extent by Roman calendars of the Roman imperial period (753 BC).
Buddhist calendars tend to use the epoch of 544 BC (date of Buddha's parinirvana).
The term Hindu calendar may refer to a number of traditional Indian calendars. A notable example of a Hindu epoch is the Vikram Samvat (58 BC),^[3] also used in modern times as the national calendars of Nepal and Bangladesh.
The Julian and Gregorian calendars use as epoch the Incarnation of Jesus as calculated in the 6th century by Dionysius Exiguus.^[4] (Subsequent research has shown that this moment is about four years after the best estimate for the date of birth of Jesus.) This epoch was applied retrospectively to the Julian calendar, long after its original creation by Julius Caesar.
The epoch of the Islamic calendar is the Hijra (AD 622). The year count in this calendar shifts relative to the solar year count, as the calendar is purely lunar: its year consists of 12 lunations and is thus ten or eleven days shorter than a solar year. This calendar denotes "lunar years" as Anno Hegiræ ([since] the year of the Hijra) or AH. This calendar is used in Sunni Islam and related sects.
The epoch of the official Iranian calendar is also the Hijra, but it is a solar calendar; each year begins at the Northern spring equinox. This calendar is used in Shia Islam and related sects.

Modern eras

The Bahá'í calendar is dated from the vernal equinox of the year the Báb proclaimed his religion (AD 1844). Years are grouped in Váḥids of 19 years, and Kull-i-Shay of 361 (19×19) years.^[5]
In Thailand in 1888 King Chulalongkorn decreed a National Thai Era dating from the founding of Bangkok on April 6, 1782. In 1912, New Year's Day was shifted to April 1. In 1941, Prime Minister Phibunsongkhram decided to count the years since 543 BC. This is the Thai solar calendar using the Thai Buddhist Era. Except for this era, it is the Gregorian calendar.
In the French Republican Calendar, a calendar used by the French government for about twelve years from late 1793, the epoch was the beginning of the "Republican Era", September 22, 1792 (the day the French First Republic was proclaimed, one day after the Convention abolished the Ancien Regime).
The Indian national calendar, introduced in 1957, follows the Saka era (AD 78).
The Minguo calendar used by officials of Taiwan and its predecessor dates from January 1, 1912, the first year after the Xinhai Revolution, which overthrew the Qing Empire.
North Korea uses a system that starts in 1912 (= Juche 1), the year of the birth of its founder Kim Il-Sung.
The Fascist Era dates to Mussolini's March on Rome in 1922, and was in use only in countries under hegemony of the Fascist regime of Benito Mussolini. It has been defunct since the fall of the Italian Social Republic in 1945.
In the scientific Before Present system of numbering years for purposes of radiocarbon dating, the reference date is January 1, 1950 (though the specific date January 1 is quite unnecessary, as radiocarbon dating has limited precision).^[6]^[7]
Different branches of Freemasonry have selected different years to date their documents according to a Masonic era, such as the Anno Lucis (A.L.).
The Holocene calendar uses 10,000 BC as the epoch, the beginning of the Holocene epoch on the geological time scale.

Regnal eras

The official Japanese system numbers years from the accession of the current emperor, regarding the calendar year during which the accession occurred as the first year. A similar system existed in China before 1912, being based on the accession year of the emperor (1911 was thus the third year of the Xuantong period). With the establishment of the Republic of China in 1912, the republican era was introduced. It is still very common in Taiwan to date events via the republican era. The People's Republic of China adopted the common era calendar in 1949 (the 38th year of the Chinese Republic).

Other applications

An epoch in computing is the time at which the representation is zero. For example, Unix time is represented as the number of seconds since 00:00:00 UTC on 1 January 1970, not counting leap seconds.

An epoch in astronomy is a reference time used for consistency in calculation of positions and orbits. A common astronomical epoch is J2000, which is noon on January 1, 2000, Terrestrial Time.

An epoch in Geochronology is a period of time, typically in the order of tens of millions of years. The current epoch is the Holocene.

References

^ Solomin, Rachel M. "Counting the Jewish Years". myjewishlearning.com. Archived from the original on 2020-02-12. Retrieved 2016-12-27.
^ Lee, Scott E. (2006). "Overview of Calendars". rosettacalendar.com. Archived from the original on 2020-08-20. Retrieved 2006-10-23.
^ Dershowitz, Nachum; Reingold, Edward M. (2008). Calendrical Calculations (3rd ed.). Cambridge University Press. p. 289. ISBN 978-0-521-70238-6.
^ Blackburn, B; Holford-Strevens, L (2003). "Incarnation era". The Oxford Companion to the Year: An exploration of calendar customs and time-reckoning. Oxford University Press. p. 881.
^ Richards, E. G. (2013). "Calendars". In Urban, S. E.; Seidelman, P. K. (eds.). Explanatory Supplement to the Astronomical Almanac (3rd ed.). Mill Valley, CA: University Science Books. pp. 616–617.
^ Higham, Thomas. "Radiocarbon dating – Age calculation". c14dating.com. Thomas Higham (archaeologist). Archived from the original on June 10, 2007. Retrieved December 31, 2009.
^ Stuiver, Minze; Polach HA (1977). "Discussion; reporting of C-14 data". Radiocarbon. 19 (3). University of Arizona: 355–363. Bibcode:1977Radcb..19..355S. doi:10.1017/S0033822200003672. S2CID 56572650. Archived from the original on August 17, 2020. Retrieved October 5, 2018.

Chronology

Key topics

Periods
Eras
Epochs

Calendar eras	Human Era Ab urbe condita Anno Domini / Common Era Anno Mundi Bosporan era Bostran era Byzantine era Seleucid era Era of Caesar (Iberia) Before present Hijri Egyptian Sothic cycle Hindu units of time (Yuga) Mesoamerican Long Count Short Count Tzolk'in Haab'
Regnal year	Anka year Canon of Kings English and British regnal year Lists of kings Limmu
Era names	Chinese Japanese Korean Vietnamese

Calendars

Pre-Julian / Julian	Pre-Julian Roman Original Julian Proleptic Julian Revised Julian
Gregorian	Gregorian Proleptic Gregorian Old Style and New Style dates Adoption of the Gregorian calendar Dual dating
Astronomical	Lunisolar (Hebrew, Hindu) Solar Lunar (Islamic) Astronomical year numbering
Others	Chinese sexagenary cycle Geologic Calendar Iranian ISO week date Mesoamerican Maya Aztec Winter count New Earth Time

Astronomic time

Geologic time

Concepts	Deep time Geological history of Earth Geological time units
Standards	Global Standard Stratigraphic Age (GSSA) Global Boundary Stratotype Section and Point (GSSP)
Methods	Chronostratigraphy Geochronology Isotope geochemistry Law of superposition Luminescence dating Samarium–neodymium dating

Chronological
dating

Absolute dating	Amino acid racemisation Archaeomagnetic dating Dendrochronology Ice core Incremental dating Lichenometry Paleomagnetism Radiometric dating Lead–lead Potassium–argon Radiocarbon Uranium–lead Tephrochronology Luminescence dating Thermoluminescence dating
Relative dating	Fluorine absorption Nitrogen dating Obsidian hydration Seriation Stratigraphy