As a

moveable feast A moveable feast is an observance in a Christian liturgical calendar which occurs on different dates in different years. It is the complement of a fixed feast, an annual celebration that is held on the same calendar date every year, such as Chri ...

, the date of Easter is determined in each year through a calculation known as – often simply ''Computus'' – or as paschalion particularly in the

Eastern Orthodox Church The Eastern Orthodox Church, officially the Orthodox Catholic Church, and also called the Greek Orthodox Church or simply the Orthodox Church, is List of Christian denominations by number of members, one of the three major doctrinal and ...

Easter Easter, also called Pascha ( Aramaic: פַּסְחָא , ''paskha''; Greek: πάσχα, ''páskha'') or Resurrection Sunday, is a Christian festival and cultural holiday commemorating the resurrection of Jesus from the dead, described in t ...

is celebrated on the first Sunday after the

Paschal full moon An ecclesiastical full moon is formally the 14th day of the ecclesiastical lunar month (an ecclesiastical moon) in an ecclesiastical lunar calendar. The ecclesiastical lunar calendar spans the year with lunar months of 30 and 29 days which are in ...

(a mathematical approximation of the first astronomical full moon, on or after 21 March itself a fixed approximation of the

March equinox The March equinox or northward equinox is the equinox on the Earth when the subsolar point appears to leave the Southern Hemisphere and cross the celestial equator, heading northward as seen from Earth. The March equinox is known as the ver ...

). Determining this date in advance requires a correlation between the

lunar month In lunar calendars, a lunar month is the time between two successive syzygies of the same type: new moons or full moons. The precise definition varies, especially for the beginning of the month. Variations In Shona, Middle Eastern, and Euro ...

s and the

solar year A tropical year or solar year (or tropical period) is the time that the Sun takes to return to the same position in the sky – as viewed from the Earth or another celestial body of the Solar System – thus completing a full cycle of astronom ...

, while also accounting for the month, date, and weekday of the Julian or

Gregorian calendar The Gregorian calendar is the calendar used in most parts of the world. It went into effect in October 1582 following the papal bull issued by Pope Gregory XIII, which introduced it as a modification of, and replacement for, the Julian cale ...

. The complexity of the

algorithm In mathematics and computer science, an algorithm () is a finite sequence of Rigour#Mathematics, mathematically rigorous instructions, typically used to solve a class of specific Computational problem, problems or to perform a computation. Algo ...

arises because of the desire to associate the date of Easter with the date of the Jewish feast of

Passover Passover, also called Pesach (; ), is a major Jewish holidays, Jewish holiday and one of the Three Pilgrimage Festivals. It celebrates the Exodus of the Israelites from slavery in Biblical Egypt, Egypt. According to the Book of Exodus, God in ...

which, Christians believe, is when Jesus was crucified. It was originally feasible for the entire Christian Church to receive the date of Easter each year through an annual announcement by the

pope The pope is the bishop of Rome and the Head of the Church#Catholic Church, visible head of the worldwide Catholic Church. He is also known as the supreme pontiff, Roman pontiff, or sovereign pontiff. From the 8th century until 1870, the po ...

. By the early third century, however, communications in the

Roman Empire The Roman Empire ruled the Mediterranean and much of Europe, Western Asia and North Africa. The Roman people, Romans conquered most of this during the Roman Republic, Republic, and it was ruled by emperors following Octavian's assumption of ...

had deteriorated to the point that the church put great value in a system that would allow the clergy to determine the date for themselves, independently yet consistently. Additionally, the church wished to eliminate dependencies on the

Hebrew calendar The Hebrew calendar (), also called the Jewish calendar, is a lunisolar calendar used today for Jewish religious observance and as an official calendar of Israel. It determines the dates of Jewish holidays and other rituals, such as '' yahrze ...

, by deriving the date for Easter directly from the March equinox. In ''

The Reckoning of Time ''The Reckoning of Time'' (, CPL 2320) is an English era treatise written in Medieval Latin by the Northumbrian monk Bede in 725. Background In mid-7th-century Anglo-Saxon England, there was a desire to see the Easter season less closel ...

'' (725),

Bede Bede (; ; 672/326 May 735), also known as Saint Bede, Bede of Jarrow, the Venerable Bede, and Bede the Venerable (), was an English monk, author and scholar. He was one of the most known writers during the Early Middle Ages, and his most f ...

uses as a general term for any sort of calculation, although he refers to the Easter cycles of

Theophilus Theophilus is a male given name with a range of alternative spellings. Its origin is the Greek word Θεόφιλος from θεός (''theós'', "God") and φιλία (''philía'', "love or affection") can be translated as "Love of God" or "Friend ...

as a "Paschal ." By the end of the 8th century, came to refer specifically to the calculation of time. The calculations produce different results depending on whether the Julian calendar or the Gregorian calendar is used. For this reason, the

Catholic Church The Catholic Church (), also known as the Roman Catholic Church, is the List of Christian denominations by number of members, largest Christian church, with 1.27 to 1.41 billion baptized Catholics Catholic Church by country, worldwid ...

and Protestant churches (which follow the Gregorian calendar) celebrate Easter on a different date from that of the Eastern and

Oriental Orthodoxy The Oriental Orthodox Churches are Eastern Christian churches adhering to Miaphysite Christology, with approximately 50 million members worldwide. The Oriental Orthodox Churches adhere to the Nicene Christian tradition. Oriental Orthodoxy is ...

(which follow the Julian calendar). It was the drift of 21 March from the observed equinox that led to the

Gregorian reform of the calendar The Gregorian calendar is the calendar used in most parts of the world. It went into effect in October 1582 following the papal bull issued by Pope Gregory XIII, which introduced it as a modification of, and replacement for, the Julian cale ...

, to bring them back into line.

History

The earliest known Roman tables were devised in 222 by

Hippolytus of Rome Hippolytus of Rome ( , ; Romanized: , – ) was a Bishop of Rome and one of the most important second–third centuries Christian theologians, whose provenance, identity and corpus remain elusive to scholars and historians. Suggested communitie ...

based on eight-year cycles. Then 84-year tables were introduced in Rome by Augustalis near the end of the 3rd century. Although a process based on the 19-year Metonic cycle was first proposed by Bishop

Anatolius of Laodicea Anatolius of Laodicea (; early 3rd century – July 3, 283"Lives of the Saints," Omer Englebert New York: Barnes & Noble Books, 1994, p. 256.), also known as Anatolius of Alexandria, was a Syro- Egyptian saint and Bishop of Laodicea on the Medi ...

around 277, the concept did not fully take hold until the Alexandrian method became authoritative in the late 4th century. The Alexandrian was converted from the

Alexandrian calendar The Coptic calendar, also called the Alexandrian calendar, is a liturgical calendar used by the farming populace in Egypt and used by the Coptic Orthodox and Coptic Catholic churches. It was used for fiscal purposes in Egypt until the adoption ...

into the Julian calendar in Alexandria around 440, which resulted in a Paschal table (attributed to pope

Cyril of Alexandria Cyril of Alexandria (; or ⲡⲓ̀ⲁⲅⲓⲟⲥ Ⲕⲓⲣⲓⲗⲗⲟⲥ; 376–444) was the Patriarch of Alexandria from 412 to 444. He was enthroned when the city was at the height of its influence and power within the Roman Empire ...

) covering the years 437 to 531. This Paschal table was the source which inspired

Dionysius Exiguus Dionysius Exiguus (Latin for "Dionysius the Humble"; Greek: Διονύσιος; – ) was a 6th-century Eastern Roman monk born in Scythia Minor. He was a member of a community of Scythian monks concentrated in Tomis (present-day Constanț ...

, who worked in Rome from about 500 to about 540, to construct a continuation of it in the form of his famous Paschal table covering the years 532 to 616. Dionysius introduced the

Christian Era The terms (AD) and before Christ (BC) are used when designating years in the Gregorian and Julian calendars. The term is Medieval Latin and means "in the year of the Lord" but is often presented using "our Lord" instead of "the Lord", tak ...

(counting years from the Incarnation of Christ) by publishing this new Easter table in 525. A modified 84-year cycle was adopted in Rome during the first half of the 4th century.

Victorius of Aquitaine Victorius of Aquitaine (), a countryman of Prosper of Aquitaine and also working in Rome, produced in AD 457 an Easter Cycle, which was based on the consular list provided by Prosper's Chronicle. This dependency caused scholars to think that Pros ...

tried to adapt the Alexandrian method to Roman rules in 457 in the form of a 532-year table, but he introduced serious errors. These Victorian tables were used in

Gaul Gaul () was a region of Western Europe first clearly described by the Roman people, Romans, encompassing present-day France, Belgium, Luxembourg, and parts of Switzerland, the Netherlands, Germany, and Northern Italy. It covered an area of . Ac ...

(now France) and Spain until they were displaced by Dionysian tables at the end of the 8th century. The tables of Dionysius and Victorius conflicted with those traditionally used in the British Isles. The British tables used an 84-year cycle, but an error made the full moons fall progressively too early. The discrepancy led to a report that Queen Eanflæd, on the Dionysian system fasted on her

Palm Sunday Palm Sunday is the Christian moveable feast that falls on the Sunday before Easter. The feast commemorates Christ's triumphal entry into Jerusalem, an event mentioned in each of the four canonical Gospels. Its name originates from the palm bran ...

while her husband

Oswiu Oswiu, also known as Oswy or Oswig (; c. 612 – 15 February 670), was King of Bernicia from 642 and of Northumbria from 654 until his death. He is notable for his role at the Synod of Whitby in 664, which ultimately brought the church in Northu ...

, king of Northumbria, feasted on his Easter Sunday. As a result of the Irish Synod of Magh-Lene in 630, the southern Irish began to use the Dionysian tables, and the northern English followed suit after the

Synod of Whitby The Synod of Whitby was a Christianity, Christian administrative gathering held in Northumbria in 664, wherein King Oswiu ruled that his kingdom would calculate Easter and observe the monastic tonsure according to the customs of Roman Catholic, Ro ...

in 664. The Dionysian reckoning was fully described by

in 725. It may have been adopted by

Charlemagne Charlemagne ( ; 2 April 748 – 28 January 814) was List of Frankish kings, King of the Franks from 768, List of kings of the Lombards, King of the Lombards from 774, and Holy Roman Emperor, Emperor of what is now known as the Carolingian ...

for the Frankish Church as early as 782 from

Alcuin Alcuin of York (; ; 735 – 19 May 804), also called Ealhwine, Alhwin, or Alchoin, was a scholar, clergyman, poet, and teacher from York, Northumbria. He was born around 735 and became the student of Ecgbert of York, Archbishop Ecgbert at Yor ...

, a follower of Bede. The Dionysian/Bedan remained in use in western Europe until the Gregorian calendar reform, and remains in use in most Eastern Churches, including the vast majority of Eastern Orthodox Churches and Non-Chalcedonian Churches. The only Eastern Orthodox church which does not follow the system is the Finnish Orthodox Church, which uses the Gregorian. Having deviated from the Alexandrians during the 6th century, churches beyond the eastern frontier of the former Byzantine Empire, including the

Assyrian Church of the East The Assyrian Church of the East (ACOE), sometimes called the Church of the East and officially known as the Holy Apostolic Catholic Assyrian Church of the East, is an Eastern Christianity, Eastern Syriac Christianity, Syriac Christian denomin ...

, now celebrate Easter on different dates from

es four times every 532 years. Apart from these churches on the eastern fringes of the Roman empire, by the tenth century all had adopted the Alexandrian Easter, which still placed the vernal equinox on 21 March, although Bede had already noted its drift in 725 it had drifted even further by the 16th century. Worse, the reckoned Moon that was used to compute Easter was fixed to the Julian year by the 19-year cycle. That approximation built up an error of one day every 310 years, so by the 16th century the

lunar calendar A lunar calendar is a calendar based on the monthly cycles of the Moon's phases ( synodic months, lunations), in contrast to solar calendars, whose annual cycles are based on the solar year, and lunisolar calendars, whose lunar months are br ...

was out of phase with the real Moon by four days. The Gregorian Easter has been used since 1583 by the

Roman Catholic Church The Catholic Church (), also known as the Roman Catholic Church, is the List of Christian denominations by number of members, largest Christian church, with 1.27 to 1.41 billion baptized Catholics Catholic Church by country, worldwid ...

and was adopted by most

Protestant Protestantism is a branch of Christianity that emphasizes Justification (theology), justification of sinners Sola fide, through faith alone, the teaching that Salvation in Christianity, salvation comes by unmerited Grace in Christianity, divin ...

churches between 1753 and 1845. German Protestant states used an astronomical Easter between 1700 and 1776, based on the ''

Rudolphine Tables The ''Rudolphine Tables'' () consist of a star catalogue and planetary tables published by Johannes Kepler in 1627, using observational data collected by Tycho Brahe (1546–1601). The tables are named in memory of Rudolf II, Holy Roman Emper ...

'' of

Johannes Kepler Johannes Kepler (27 December 1571 – 15 November 1630) was a German astronomer, mathematician, astrologer, Natural philosophy, natural philosopher and writer on music. He is a key figure in the 17th-century Scientific Revolution, best know ...

, which were in turn based on astronomical positions of the Sun and Moon observed by

Tycho Brahe Tycho Brahe ( ; ; born Tyge Ottesen Brahe, ; 14 December 154624 October 1601), generally called Tycho for short, was a Danish astronomer of the Renaissance, known for his comprehensive and unprecedentedly accurate astronomical observations. He ...

at his

Uraniborg Uraniborg was an astronomical observatory and alchemy laboratory established and operated by the Danish astronomer Tycho Brahe. It was the first custom-built observatory in modern Europe, and the last to be built without a telescope as its pr ...

observatory on the island of

Ven Venezuela, officially the Bolivarian Republic of Venezuela, is a country on the northern coast of South America, consisting of a continental landmass and many islands and islets in the Caribbean Sea. It comprises an area of , and its popul ...

, while Sweden used it from 1739 to 1844. This astronomical Easter was the Sunday after the full moon instant that was after the vernal equinox instant using Uraniborg time . However, it was delayed one week if that Sunday was the Jewish date Nisan15, the first day of Passover week, calculated according to modern Jewish methods. This Nisan15 rule affected two Swedish years, 1778 and 1798, that instead of being one week before the Gregorian Easter, were delayed one week so they were on the same Sunday as the Gregorian Easter. Germany's astronomical Easter was one week before the Gregorian Easter in 1724 and 1744. Sweden's astronomical Easter was one week before the Gregorian Easter in 1744, but one week after it in 1805, 1811, 1818, 1825, and 1829. Two modern astronomical Easters were proposed but never used by any Church. The first was proposed as part of the

Revised Julian calendar The Revised Julian calendar, or less formally the new calendar and also known as the Milanković calendar, is a calendar proposed in 1923 by the Serbian scientist Milutin Milanković as a more accurate alternative to both Julian calendar, Julian ...

at a Synod in

Constantinople Constantinople (#Names of Constantinople, see other names) was a historical city located on the Bosporus that served as the capital of the Roman Empire, Roman, Byzantine Empire, Byzantine, Latin Empire, Latin, and Ottoman Empire, Ottoman empire ...

in 1923 and the

second The second (symbol: s) is a unit of time derived from the division of the day first into 24 hours, then to 60 minutes, and finally to 60 seconds each (24 × 60 × 60 = 86400). The current and formal definition in the International System of U ...

was proposed by a 1997

World Council of Churches The World Council of Churches (WCC) is a worldwide Christian inter-church organization founded in 1948 to work for the cause of ecumenism. Its full members today include the Assyrian Church of the East, most jurisdictions of the Eastern Orthodo ...

Consultation in

Aleppo Aleppo is a city in Syria, which serves as the capital of the Aleppo Governorate, the most populous Governorates of Syria, governorate of Syria. With an estimated population of 2,098,000 residents it is Syria's largest city by urban area, and ...

in 1997. Both used the same rule as the German and Swedish versions but used modern astronomical calculations and

Jerusalem Jerusalem is a city in the Southern Levant, on a plateau in the Judaean Mountains between the Mediterranean Sea, Mediterranean and the Dead Sea. It is one of the List of oldest continuously inhabited cities, oldest cities in the world, and ...

time without the Nisan15 rule. The 1923 version would have placed the astronomical Easter one month before the Gregorian Easter in 1924, 1943, and 1962, but one week after it in 1927, 1954, and 1967. The 1997 version would have placed the astronomical Easter on the same Sunday as the Gregorian Easter for 2000–2025 except for 2019, when it would have been one month earlier. At the

Second Vatican Council The Second Ecumenical Council of the Vatican, commonly known as the or , was the 21st and most recent ecumenical council of the Catholic Church. The council met each autumn from 1962 to 1965 in St. Peter's Basilica in Vatican City for session ...

, the Catholic Church stated that it had no objections to the feast of Easter being moved to a fixed Sunday subject to ecumenical agreement on the date, or to the adoption of a fixed date for civil purposes so long as this did not compromise the occurrence of Easter on a Sunday and the maintenance of a seven-day week.

Theory

The Easter cycle groups days into lunar months, which are either 29 or 30 days long. There is an exception. The month ending in March normally has 30 days, but if 29 February of a leap year falls within it, it contains 31. As these groups are based on the

lunar cycle A lunar phase or Moon phase is the apparent shape of the Moon's directly sunlit portion as viewed from the Earth. Because the Moon is tidally locked with the Earth, the same hemisphere is always facing the Earth. In common usage, the four majo ...

, over the long term the average month in the lunar calendar is a very good approximation of the

synodic month In lunar calendars, a lunar month is the time between two successive Syzygy (astronomy), syzygies of the same type: new moons or full moons. The precise definition varies, especially for the beginning of the month. Variations In Shona people, S ...

, which is days long. There are 12 synodic months in a lunar year, totaling either 354 or 355 days. The lunar year is about 11 days shorter than the calendar year, which is either 365 or 366 days long. These days by which the solar year exceeds the lunar year are called

epact The epact (, from () = added days) used to be described by medieval computists as the age of a phase of the Moon in days on 22 March; in the newer Gregorian calendar, however, the epact is reckoned as the age of the ecclesiastical moon on 1 ...

s (). It is necessary to add them to the day of the solar year to obtain the correct day in the lunar year. Whenever the epact reaches or exceeds 30, an extra

intercalary month Intercalation or embolism in timekeeping is the insertion of a leap day, week, or month into some calendar years to make the calendar follow the seasons or moon phases. Lunisolar calendars may require intercalations of days or months. Solar ca ...

(or embolismic month) of 30 days must be inserted into the lunar calendar: then 30 must be subtracted from the epact. Charles Wheatly provides the detail: Thus the lunar month took the name of the Julian month in which it ended. The nineteen-year Metonic cycle assumes that 19 tropical years are as long as 235 synodic months. So after 19 years the lunations should fall the same way in the solar years, and the epacts should repeat. Over 19 years the epact increases by , not . That is, 209 divided by 30 leaves a remainder of 29 instead of being a multiple of 30. This is a problem if compensation is only done by adding months of 30 days. So after 19 years, the epact must be corrected by one day for the cycle to repeat. This is the so-called ("leap of the moon"). The Julian calendar handles it by reducing the length of the lunar month that begins on 1 July in the last year of the cycle to 29 days. This makes three successive 29-day months. The and the seven extra 30-day months were largely hidden by being located at the points where the Julian and lunar months begin at about the same time. The extra months commenced on 1 January (year 3), 2 September (year 5), 6 March (year 8), 3 January (year 11), 31 December (year 13), 1 September (year 16), and 5 March (year 19). The sequence number of the year in the 19-year cycle is called the " golden number", and is given by the formula :''GN'' = (''Y'' mod 19) + 1 That is, the year number ''Y'' in the

Christian era The terms (AD) and before Christ (BC) are used when designating years in the Gregorian and Julian calendars. The term is Medieval Latin and means "in the year of the Lord" but is often presented using "our Lord" instead of "the Lord", tak ...

is divided by 19, and the remainder plus 1 is the golden number. (Some sources specify that you add 1 ''before'' taking the remainder; in that case, you need to treat a result of 0 as golden number 19. In the formula above we take the remainder first and ''then'' add 1, so no such adjustment is necessary.) Cycles of 19 years are not all the same length, because they may have either four or five leap years. But a period of four cycles, 76 years (a Callippic cycle), has a length of days (if it does not cross a century division). There are lunar months in this period, so the average length is 27759/940 or about 29.530851 days. There are usual nominal 30-day lunar months and the same number of usual nominal 29-day months, but with 19 of these lengthened by a day on leap days, plus 24 intercalated months of 30 days and four intercalated months of 29 days. Since this is longer than the true length of a synodic month, about 29.53059 days, the calculated Paschal full moon gets later and later compared to the astronomical full moon, unless a correction is made as in the Gregorian system (see below). The paschal or Easter-month is the first one in the year to have its fourteenth day (its formal full moon) on or after 21 March. Easter is the Sunday after its 14th day (or, saying the same thing, the Sunday within its third week). The paschal lunar month always begins on a date in the 29-day period from 8 March to 5 April inclusive. Its fourteenth day, therefore, always falls on a date between 21 March and 18 April inclusive (in the Gregorian or Julian calendar, for the Western and Eastern system, resp.), and the following Sunday then necessarily falls on a date in the range 22 March to 25 April inclusive. However, in the Western system Easter cannot fall on 22 March during the 300-year period 1900–2199 (see below). In the solar calendar Easter is called a

since its date varies within a 35-day range. But in the lunar calendar, Easter is always the third Sunday in the paschal lunar month, and is no more "moveable" than any holiday that is fixed to a particular day of the week and week within a month, such as

Thanksgiving Thanksgiving is a national holiday celebrated on various dates in October and November in the United States, Canada, Saint Lucia, Liberia, and unofficially in countries like Brazil and Germany. It is also observed in the Australian territory ...

Tabular methods

Gregorian reform of the

As reforming the was the primary motivation for the introduction of the

in 1582, a corresponding methodology was introduced alongside the new calendar. The general method of working was given by Clavius in the Six Canons (1582), and a full explanation followed in his (1603). Easter is the Sunday following the Paschal full moon date. The paschal full moon date is the ecclesiastical full moon date on or after the ecclesiastical equinox on 21 March. The fourteenth day of the lunar month is ecclesiastically considered the day of the full moon. It is the day of the lunar month on which the moment of opposition ("full moon") is most likely to fall. The Gregorian method derives new moon dates by determining the

for each year. The epact can have a value from * (0 or 30) to 29 days. It is the age of the moon in days (i.e. the lunar date) on 1 January reduced by one day. The "new moon" is most likely to become visible (as a slender crescent in the western sky after sunset) on the first day of the lunar month. The conjunction of Sun and Moon ("new moon") is most likely to fall on the preceding day, which is day 29 of a "hollow" (29-day) month and day 30 of a "full" (30-day) month. Historically, in

Beda Venerabilis' Easter cycle In the year 616 an anonymous scholar extended Dionysius Exiguus' Easter table to an Easter table covering the years 532 up to and including 721. Dionysius' table was published in 525 and only a century later accepted by the church of Rome, which ...

, the paschal full moon date for a year was found from its sequence number in the Metonic cycle, called the golden number, which cycle repeats the lunar phase on January 1 every 19 years. This method was modified in the Gregorian reform because the tabular dates go out of sync with reality after about two centuries. From the epact method, a simplified table can be constructed that has a validity of one to three centuries. The date of the paschal full moon in a particular year is usually either 11 days earlier than in the previous year, or 19 days later. In 5 out of 19 years it is one day less: in years 1, 6, and 17 of the cycle the date is only 18 days later, and in years 7 and 18 it is only 10 days earlier than in the previous year. In the Eastern system, the Paschal full moon is usually four days later than in the West. It is 34 days later in 5 of the 19 years, and 5 days later in years 6 and 17, because in those years, the Gregorian system puts the Paschal full moon a day earlier than it would normally be, in order to keep Easter before April 26, as explained below. In the year 2100, the difference will increase by another day.

Calendarium

The epacts are used to find the dates of the new moon in the following way: Write down a table of all 365 days of the year (the leap day is ignored). Then label all dates with a

Roman numeral Roman numerals are a numeral system that originated in ancient Rome and remained the usual way of writing numbers throughout Europe well into the Late Middle Ages. Numbers are written with combinations of letters from the Latin alphabet, ea ...

counting downwards, from "*" (0 or 30), "xxix" (29), down to "i" (1), starting from 1 January, and repeat this to the end of the year. However, in every second such period count only 29 days and label the date with xxv (25) also with xxiv (24). Treat the 13th period (last eleven days) as long, therefore, and assign the labels "xxv" and "xxiv" to sequential dates (26 and 27 December respectively). Add the label "25" to the dates that have "xxv" in the 30-day periods; but in 29-day periods (which have "xxiv" together with "xxv") add the label "25" to the date with "xxvi". The distribution of the lengths of the months and the length of the epact cycles is such that each civil calendar month starts and ends with the same epact label, except for February and, one might say, for August, which starts with the double label "xxv"/"xxiv" but ends with the single label "xxiv". This table is called the . The ecclesiastical new moons for any year are those dates when the epact for the year is entered. If the epact for the year is for instance 27, then there is an ecclesiastical new moon on every date in that year that has the epact label "xxvii" (27). If the epact is 25, then there is a complication, introduced so that the ecclesiastical new moon will not fall on the same date twice during a Metonic cycle. If the epact cycle in force includes epact 24 (as does the cycle in use since 1900 and until 2199), then an epact of 25 puts the ecclesiastical new moon on April 4 (having the label "25"), otherwise it is on April 5 (having label "xxv"). An epact of 25 giving April 4 can only happen if the golden number is greater than 11. In which case it will be 11 years after a year with epact 24. So for example, in 1954 the golden number was 17, the epact was 25, the ecclesiastical new moon was reckoned on April 4, the full moon on April 17. Easter was on April 18 rather than April 25 as it would otherwise have been, such as in 1886 when the golden number was 6. This system automatically intercalates seven months per Metonic cycle. Label all the dates in the table with letters "A" to "G", starting from 1 January, and repeat to the end of the year. If, for instance, the first Sunday of the year is on 5 January, which has letter "E", then every date with the letter "E" is a Sunday that year. Then "E" is called the dominical letter (DL) for that year – from . The dominical letter cycles backward one position every year. In leap years, after 24 February, the Sundays fall on the previous letter of the cycle, so leap years have two dominical letters: the first for before, the second for after the leap day. In practice, for the purpose of calculating Easter, this need not be done for all 365 days of the year. For the epacts, March comes out exactly the same as January, because = so one need not calculate January or February. To avoid the need to calculate the dominical letters for January and February, start with D for 1 March. You need the epacts only from 8 March to 5 April. As an example, if the epact is 27, an ecclesiastical new moon falls on every date labeled ''xxvii''. The ecclesiastical full moon falls 13 days later. From the table above, this gives new moons on 4 March and 3 April, and so full moons on 17 March and 16 April. Then Easter Day is the first Sunday after the first ecclesiastical full moon on or after 21 March. In the example, this paschal full moon is on 16 April. If the dominical letter is E, then Easter day is on 20 April.

Corrections

The label "''25''" (as distinct from "xxv") is used as follows: Within a Metonic cycle, years that are 11 years apart have epacts that differ by one day. A month beginning on a date having labels "xxiv" and "xxv" written side by side has either 29 or 30 days. If the epacts 24 and 25 both occur within one Metonic cycle, then the new (and full) moons would fall on the same dates for these two years. This is possible for the real moon but is inelegant in a schematic lunar calendar; the dates should repeat only after 19 years. To avoid this, in years that have epacts 25 and with a Golden Number larger than 11, the reckoned new moon falls on the date with the label ''25'' rather than ''xxv''. Where the labels ''25'' and ''xxv'' are together, there is no problem since they are the same. This does not move the problem to the pair "25" and "xxvi", because the earliest epact 26 could appear would be in year 23 of the cycle, which lasts only 19 years: there is a in between that makes the new moons fall on separate dates. The Gregorian calendar has a correction to the tropical year by dropping three leap days in 400 years (always in a century year). This is a correction to the length of the tropical year, but should have no effect on the Metonic relation between years and lunations. Therefore, the epact is compensated for this (partially see

) by subtracting one in these century years. This is the so-called solar correction or "solar equation" ("equation" being used in its medieval sense of "correction"). However, 19 uncorrected Julian years are a little longer than 235 lunations. The difference accumulates to one day in about 308 years, or 0.00324 days per year. In one cycle, the epact decreases due to the solar correction by 19 × 0.0075 = 0.1425 on average, so a cycle is equivalent to months, whereas there are actually 19 × 365.2425 / 29.5305889 ≈ 234.997261 synodic months. The difference of 0.002011 synodic months per 19-year cycle, or 0.003126 days per year, necessitates an occasional lunar correction to the epact. In the Gregorian calendar, this is done by adding 1 eight times in 2,500 (Gregorian) years (slightly more than 2500 × 0.003126, or about 7.8), always in a century year: this is the so-called lunar correction (historically called "lunar equation"). The first one was applied in 1800, the next is in 2100, and will be applied every 300 years except for an interval of 400 years between 3900 and 4300, which starts a new cycle. At the time of the reform, the epacts were changed by 7, even though 10 days were skipped, in order to make a three-day correction to the timing of the new moons. The solar and lunar corrections work in opposite directions, and in some century years (for example, 1800 and 2100) they cancel each other. The result is that the Gregorian lunar calendar uses an epact table that is valid for a period of from 100 to 300 years. The epact table listed above is valid for the 20th, 21st and 22nd century. As explained below, the dates of Easter repeat after 5.7 million years, and over this period the average length of an ecclesiastical month is 2,081,882,250/70,499,183 ≈ 29.5305869 days, which differs from the current actual mean lunation length (29,5305889 d: see Lunar month#Synodic month) in the 6th figure after the decimal point. This corresponds to an error of less than a day in the phase of the moon over 40,000 years, but in fact the length of a day is changing (as is the length of a synodic month), so the system is not accurate over such periods. See the article

ΔT (timekeeping) In precise timekeeping, Δ''T'' (Delta ''T'', delta-''T'', delta''T'', or D''T'') is a measure of the cumulative effect of the departure of the Earth's rotation period from the fixed-length day of International Atomic Time (86,400 second ...

for information on the cumulative change of day length.

Details

This method of computation has several subtleties: Every other lunar month has only 29 days, so one day must have two (of the 30) epact labels assigned to it. The reason for moving around the epact label "xxv/25" rather than any other seems to be the following: According to Dionysius (in his introductory letter to Petronius), the Nicene council, on the authority of

Eusebius Eusebius of Caesarea (30 May AD 339), also known as Eusebius Pamphilius, was a historian of Christianity, exegete, and Christian polemicist from the Roman province of Syria Palaestina. In about AD 314 he became the bishop of Caesarea Maritima. ...

, established that the first month of the ecclesiastical lunar year (the paschal month) should start between 8 March and 5 April inclusive, and the 14th day fall between 21 March and 18 April inclusive, thus spanning a period of (only) 29 days. A new moon on 7 March, which has epact label "xxiv", has its 14th day (full moon) on 20 March, which is too early (not following 20 March). So years with an epact of "xxiv", if the lunar month beginning on 7 March had 30 days, would have their paschal new moon on 6 April, which is too late: The full moon would fall on 19 April, and Easter could be as late as 26 April. In the Julian calendar the latest date of Easter was 25 April, and the Gregorian reform maintained that limit. So the paschal full moon must fall no later than 18 April and the new moon on 5 April, which has epact label "xxv". 5 April must therefore have its double epact labels "xxiv" and "xxv". Then epact "xxv" must be treated differently, as explained in the previous section. The frequency distribution for the date of Easter is ill-defined, because every 100 to 300 years the mapping from golden number to epact changes, and the long-term frequency distribution is only valid over a period of millions of years (see below), whereas the system will certainly not be used for that long. The present mapping, valid from 1900 to 2199, gives Easter dates with highly varying frequencies. March 22 can never occur, whereas March 31 occurs 13 times in this 300-year span. If one does ask the question of what the distribution would be over the whole 5.7-million-year period after which the dates repeat, this distribution is quite different from the distribution in the period 1900 to 2199, or even the distribution over the period since the reform until now. The date of Easter in a given year depends only on the epact for the year, its golden number, and its dominical letter, which tells us which days are Sundays. If we go forward 3,230,000 years from a particular year, we find a year at the same point in the 400-year Gregorian cycle and with the same golden number, but with the epact augmented by 1. Therefore, in the long term, all thirty epacts are equally likely. On the other hand, the dominical letters do not all have the same frequency – years with the letters A and C (at the end of the year) occur 14% of the time each, E and F occur 14.25% of the time, and B, D, and G occur 14.5% of the time. Taking into consideration the complication having to do with epact 25, this gives the distribution shown in the second graph. April 19 is the most common because when the epact is 25 the ecclesiastical full moon falls on April 17 or 18 (depending on the golden number), and it also falls on these dates when the epact is 26 or 24, respectively. There are seven days on which the full moon can fall, including April 17 and April 18, in order for Easter to be on April 19 (this is also the latest possible Easter date that the ecclesiastical full moon can fall on a Saturday, as April 18 is the latest date for the ecclesiastical full moon, which Easter is next day if the ecclesiastical full moon is on a Saturday). As a consequence, 19 April is the date on which Easter falls most frequently in the Gregorian calendar, happening about 1 year in every 26. 22 March is the least frequent, occurring in just years. The relation between lunar and solar calendar dates is made independent of the leap day scheme for the solar year. Basically the Gregorian calendar still uses the Julian calendar with a leap day every four years, so a Metonic cycle of 19 years has 6,940 or 6,939 days with five or four leap days. Now the lunar cycle counts only . By not labeling and counting the leap day with an epact number, but having the next new moon fall on the same calendar date as without the leap day, the current lunation gets extended by a day, and the 235 lunations cover as many days as the 19 years (so long as the 19 years do not include a "solar correction" as in 1900). So the burden of synchronizing the calendar with the moon (intermediate-term accuracy) is shifted to the solar calendar, which may use any suitable intercalation scheme, all under the assumption that 19 solar years = 235 lunations (creating a long-term inaccuracy if not corrected by a "lunar correction"). A consequence is that the reckoned age of the moon may be off by a day, and also that the lunations that contain the leap day may be 31 days long, which would never happen if the real moon were followed (short-term inaccuracies). This is the price of a regular fit to the solar calendar. From the perspective of those who might wish to use the Gregorian Easter cycle as a calendar for the entire year, there are some flaws in the Gregorian lunar calendar (although they have no effect on the paschal month and the date of Easter): # Lunations of 31 (and sometimes 28) days occur. # If a year with Golden Number 19 happens to have epact 19, then the last ecclesiastical new moon falls on 2 December; the next would be due on 1 January. However, at the start of the new year, a increases the epact by another unit, and the new moon should have occurred on the previous day. So a new moon is missed. The of the takes account of this by assigning epact label "19" instead of "xx" to 31 December of such a year, making that date the new moon. It happened every 19 years when the original Gregorian epact table was in effect (for the last time in 1690), and next happens in 8511. # If the epact of a year is 20, an ecclesiastical new moon falls on 31 December. If that year falls before a century year, then in most cases, a solar correction reduces the epact for the new year by one: The resulting epact "*" means that another ecclesiastical new moon is counted on 1 January. So, formally, a lunation of one day has passed. This next happens in 4199–4200. # Other borderline cases occur (much) later, and if the rules are followed strictly and these cases are not specially treated, they generate successive new moon dates that are 1, 28, 59, or (very rarely) 58 days apart. A careful analysis shows that through the way they are used and corrected in the Gregorian calendar, the epacts are actually of a lunation and not full days. See

for a discussion. The solar and lunar corrections repeat after centuries. In that period, the epact for a given golden number changes by a total of . This is prime to the 30 possible epacts, so it takes before the epact mappings repeat; and centuries before they repeat at the same golden number. It is not obvious how many ecclesiastic New Moons are counted in this 5.7 Myr period. The Metonic cycles add up to = 70,500,000 lunations. But there are net corrections to the epacts, which divided by 30 add up to a correction of −817 lunations, for a total of 70,499,183 lunations. This number appears to have been first derived by

Magnus Georg Paucker Magnus Georg von Paucker (; – ) was a Baltic German astronomer and mathematician and the first Demidov Prize winner in 1832 for his work ''Handbuch der Metrologie Rußlands und seiner deutschen Provinzen''. Biography Paucker was born in the ...

in 1837. It is also mentioned in the chapter on calendars (p. 744) in the Nautical Almanac of 1931 and in the Explanatory Supplement of 1992 (p. 582). So the Gregorian Easter dates repeat in exactly the same order only after 5,700,000 years, 70,499,183 lunations, or 2,081,882,250 days; the mean lunation length is then 2,081,882,250/70,499,183 = 29.53058690 days. Of course the calendar would have to be adjusted after a few millennia because of changes in the length of the tropical year, the synodic month, and the day. Easter_date_graphs

This raises the question why the Gregorian lunar calendar has separate solar and lunar corrections, which sometimes cancel each other. Lilius's original work has not been preserved, but his proposal was described in the circulated in 1577, in which it is explained that the correction system he devised was to be a perfectly flexible tool in the hands of future calendar reformers, since the solar and lunar calendar could henceforth be corrected without mutual interference. An example of this flexibility was provided through an alternative intercalation sequence derived from Copernicus's theories, along with its corresponding epact corrections. The "solar corrections" approximately undo the effect of the Gregorian modifications to the leap days of the solar calendar on the lunar calendar: they (partially) bring the epact cycle back to the original Metonic relation between the Julian year and lunar month. The inherent mismatch between Sun and Moon in this basic 19-year cycle is then corrected every three or four centuries by the "lunar correction" to the epacts. However, the epact corrections occur at the beginning of Gregorian centuries, not Julian centuries, and therefore the original Julian Metonic cycle is not fully restored. While the net subtractions could be distributed evenly over 10,000 years (as has been proposed for example by ) if the corrections are combined, then the inaccuracies of the two cycles are also added and cannot be corrected separately. The ratios of (mean solar) days per year and days per lunation change both because of intrinsic long-term variations in the orbits, and because the rotation of the Earth is slowing down due to tidal deceleration, so the Gregorian parameters become increasingly obsolete. This does affect the date of the equinox, but it so happens that the interval between northward (northern hemisphere spring) equinoxes has been fairly stable over historical times, especially if measured in mean solar time. Also the drift in ecclesiastical full moons calculated by the Gregorian method compared to the true full moons is affected less than one would expect, because the increase in the length of the day is almost exactly compensated for by the increase in the length of the month, as tidal braking transfers angular momentum of the rotation of the Earth to orbital angular momentum of the Moon. The Ptolemaic value of the length of the mean synodic month, established around the 4th century BCE by the Babylonians, is (see Kidinnu); the current value is 0.46 s less (see

new moon In astronomy, the new moon is the first lunar phase, when the Moon and Sun have the same ecliptic longitude. At this phase, the lunar disk is not visible to the naked eye, except when it is silhouetted against the Sun during a solar eclipse. ...

). In the same historic stretch of time, the length of the mean tropical year has diminished by about 10 s. (All values mean solar time.)

British Calendar Act and ''Book of Common Prayer''

The portion of the tabular methods section above describes the historical arguments and methods by which the present dates of Easter Sunday were decided in the late 16th century by the Catholic Church. In Britain, where the Julian calendar was then still in use, Easter Sunday was defined, from 1662 to 1752 (in accordance with previous practice), by a simple table of dates in the

Anglican Anglicanism, also known as Episcopalianism in some countries, is a Western Christianity, Western Christian tradition which developed from the practices, liturgy, and identity of the Church of England following the English Reformation, in the ...

Book of Common Prayer The ''Book of Common Prayer'' (BCP) is the title given to a number of related prayer books used in the Anglican Communion and by other Christianity, Christian churches historically related to Anglicanism. The Book of Common Prayer (1549), fi ...

'' (decreed by the

Act of Uniformity 1662 The Act of Uniformity 1662 ( 14 Cha. 2. c. 4) is an act of the Parliament of England. (It was formerly cited as 13 & 14 Cha. 2. c. 4, by reference to the regnal year when it was passed on 19 May 1662.) It prescribed the form of public prayer ...

). The table was indexed directly by the golden number and the Sunday letter, which (in the Easter section of the book) were presumed to be already known. For the British Empire and colonies, the new determination of the date of Easter Sunday was defined by what is now called the Calendar (New Style) Act 1750 in an annexe that declares its effect on the ''

''. The method was chosen to give dates agreeing with the Gregorian rule already in use elsewhere, without recognising any Papal authority. As the

Church of England The Church of England (C of E) is the State religion#State churches, established List of Christian denominations, Christian church in England and the Crown Dependencies. It is the mother church of the Anglicanism, Anglican Christian tradition, ...

is the established church, Parliament could (and did) require that the dates in the ''Book of Common Prayer'' be modified accordingly, and therefore it is the general Anglican rule. The original act can be seen in the British ''Statutes at Large 1765''. The annexe to the act includes the definition: "''Easter-day'' (on which the rest depend) is always the first ''Sunday'' after the ''Full Moon'', which happens upon, or next after the Twenty-first Day of ''March''. And if the ''Full Moon'' happens upon a ''Sunday'', ''Easter-day'' is the ''Sunday'' after." The annexe subsequently uses the terms "Paschal Full Moon" and "Ecclesiastical Full Moon", making it clear that they approximate to the real full moon. The method is quite distinct from that described above in . For a general year, one first determines the golden number, then one uses three tables to determine the Sunday letter, a "cypher", and the date of the paschal full moon, from which the date of Easter Sunday follows. The epact does not explicitly appear. Simpler tables can be used for limited periods (such as 1900–2199) during which the cypher (which represents the effect of the solar and lunar corrections) does not change. Clavius's details were employed in the construction of the method, but they play no subsequent part in its use. J. R. Stockton shows his derivation of an efficient computer algorithm traceable to the tables in the prayer book and the Calendar Act (assuming that a description of how to use the Tables is at hand), and verifies its processes by computing matching tables.

"Paradoxical" Easter dates

Due to the discrepancies between the approximations of Computistical calculations of the time of the

mean A mean is a quantity representing the "center" of a collection of numbers and is intermediate to the extreme values of the set of numbers. There are several kinds of means (or "measures of central tendency") in mathematics, especially in statist ...

(northern hemisphere) vernal equinox and the lunar phases, and the true values computed according to astronomical principles, differences occasionally arise between the date of Easter according to computistical reckoning and the hypothetical date of Easter calculated by astronomical methods using the principles attributed to the Church fathers. These discrepancies are called "paradoxical" Easter dates. In his of 1474,

Regiomontanus Johannes Müller von Königsberg (6 June 1436 – 6 July 1476), better known as Regiomontanus (), was a mathematician, astrologer and astronomer of the German Renaissance, active in Vienna, Buda and Nuremberg. His contributions were instrument ...

computed the exact time of all conjunctions of the Sun and Moon for the longitude of

Nuremberg Nuremberg (, ; ; in the local East Franconian dialect: ''Nämberch'' ) is the Franconia#Towns and cities, largest city in Franconia, the List of cities in Bavaria by population, second-largest city in the States of Germany, German state of Bav ...

according to the Alfonsine Tables for the period from 1475 to 1531. In his work he tabulated 30 instances where the Easter of the Julian disagreed with Easter computed using astronomical

New Moon In astronomy, the new moon is the first lunar phase, when the Moon and Sun have the same ecliptic longitude. At this phase, the lunar disk is not visible to the naked eye, except when it is silhouetted against the Sun during a solar eclipse. ...

. In eighteen cases the date differed by a week, in seven cases by 35 days, and in five cases by 28 days. Ludwig Lange investigated and classified different types of paradoxical Easter dates using the Gregorian . In cases where the first vernal full moon according to astronomical calculation occurs on a Sunday and the gives the same Sunday as Easter, the celebrated Easter occurs one week in advance compared to the hypothetical "astronomically" correct Easter. Lange called this case a negative weekly (hebdomadal) paradox (H− paradox). If the astronomical calculation gives a Saturday for the first vernal full moon and Easter is not celebrated on the directly following Sunday but one week later, Easter is celebrated according to the one week too late in comparison to the astronomical result. He classified such cases a positive weekly (hebdomadal) paradox (H+ paradox). The discrepancies are even larger if there is a difference according to the vernal equinox with respect to astronomical theory and the approximation of the . If the astronomical equinoctial full moon falls before the computistical equinoctial full moon, Easter will be celebrated four or even five weeks too late. Such cases are called a positive equinoctial paradox (A+ paradox) according to Lange. In the reverse case when the Computistical equinoctial full moon falls a month before the astronomical equinoctial full moon, Easter is celebrated four or five weeks too early. Such cases are called a negative equinoctial paradox (A− paradox). Equinoctial paradoxes are always valid globally for the whole Earth, because the sequence of equinox and full moon does not depend on the geographical longitude. In contrast, weekly paradoxes are local in most cases and are valid only for part of the Earth, because the change of day between Saturday and Sunday is dependent on the geographical longitude. The computistical calculations are based on astronomical tables valid for the longitude of Venice, which Lange called the Gregorian longitude. In the 21st and 22nd centuries negative weekly paradoxical Easter dates occur in 2049, 2076, 2106, 2119 (global), 2133, 2147, 2150, 2170, and 2174. Positive weekly paradoxical dates occur in 2045, 2069, 2089 (global), and 2096. Positive equinoctial paradoxical dates in 2019, 2038, 2057, 2076, 2095, 2114, 2133, 2152, 2171, and 2190. In 2076 and 2133, double paradoxes (positive equinoctial and negative weekly) occur. Negative equinoctial paradoxes are extremely rare. They occur only twice until the year 4000 in 2353, when Easter is five weeks too early and in 2372, when Easter is four weeks too early.

Algorithms

Note on operations

When expressing Easter algorithms without using tables, it has been customary to employ only the integer operations

addition Addition (usually signified by the Plus and minus signs#Plus sign, plus symbol, +) is one of the four basic Operation (mathematics), operations of arithmetic, the other three being subtraction, multiplication, and Division (mathematics), divis ...

subtraction Subtraction (which is signified by the minus sign, –) is one of the four Arithmetic#Arithmetic operations, arithmetic operations along with addition, multiplication and Division (mathematics), division. Subtraction is an operation that repre ...

multiplication Multiplication is one of the four elementary mathematical operations of arithmetic, with the other ones being addition, subtraction, and division (mathematics), division. The result of a multiplication operation is called a ''Product (mathem ...

, division,

modulo In computing and mathematics, the modulo operation returns the remainder or signed remainder of a division, after one number is divided by another, the latter being called the '' modulus'' of the operation. Given two positive numbers and , mo ...

, and assignment as it is compatible with the use of simple mechanical or electronic calculators. That restriction is undesirable for computer programming, where conditional operators and statements, as well as look-up tables, are available. One can easily see how conversion from day-of-March (22 to 56) to day-and-month (22 March to 25 April) can be done as . More importantly, using such conditionals also simplifies the core of the Gregorian calculation.

Gauss's Easter algorithm

In 1800, the mathematician

Carl Friedrich Gauss Johann Carl Friedrich Gauss (; ; ; 30 April 177723 February 1855) was a German mathematician, astronomer, geodesist, and physicist, who contributed to many fields in mathematics and science. He was director of the Göttingen Observatory and ...

presented this algorithm for calculating the date of the Julian or Gregorian Easter. He corrected the expression for calculating the variable ''p'' in 1816. In 1800, he incorrectly stated . In 1807, he replaced the condition with the simpler . In 1811, he limited his algorithm to the 18th and 19th centuries only, and stated that 26 April is always replaced with 19, and 25 April by 18 April in the circumstances stated. In 1816, he thanked his student Peter Paul Tittel for pointing out that ''p'' was wrong in the original version. gauss_computus_paschalis: input(year, calendar) a = year % 19 b = year % 4 c = year % 7 if calendar is GREGORIAN: k = year // 100 p = (13 + 8 * k) // 25 # fixed (1816), was: k // 3 q = k // 4 M = (15 - p + k - q) % 30 N = (4 + k - q) % 7 else if calendar is JULIAN: M = 15 N = 6 d = (19 * a + M) % 30 e = (2 * b + 4 * c + 6 * d + N) % 7 march_easter = d + e + 22 april_easter = d + e - 9 if april_easter

25 and d

28 and e

6 and a > 10: # changed (1807), was: (11 * M + 11) % 30 < 19 april_easter = 18 if april_easter

26 and d

29 and e

6: april_easter = 19 if march_easter <= 31: output(3, march_easter) else: output(4, april_easter) Gauss's Easter algorithm can be divided into two parts for analysis. The first part is the approximate tracking of the lunar orbiting and the second part is the exact deterministic offsetting to obtain a Sunday following the full moon. The first part consists of determining the variable ''d'', the number of days (counting from 22 March) to the day after the full moon. The formula for ''d'' contains the terms 19''a'' and the constant ''M''. ''a'' is the year's position in the 19-year lunar phase cycle, in which by assumption the moon's movement relative to Earth repeats every 19 calendar years. In older times, 19 calendar years were equated to 235 lunar months (the Metonic cycle), which is a close approximation since 235 lunar months amount to 6939.6813 days and 19 solar years are on average 6939.6075 days. The expression (19''a'' + ''M'') mod 30 repeats every 19 years within each century as ''M'' is determined per century. The 19-year cycle has nothing to do with the '19' in 19''a''; it is just a coincidence that another '19' appears. The '19' in 19''a'' comes from correcting the mismatch between a calendar year and an integer number of lunar months. A calendar year (non-leap year) has 365 days and the closest one can come with an integer number of lunar months is days. The difference is 11 days, which must be corrected for by moving the following year's occurrence of a full moon 11 days back. But in modulo 30 arithmetic, subtracting 11 is the same as adding 19, hence the addition of 19 for each year added, i.e. 19''a''. The ''M'' in serves to have a correct starting point at the start of each century. It is determined by a calculation taking the number of leap years up until that century where ''k'' inhibits a leap day every 100 years and ''q'' reinstalls it every 400 years, yielding as the total number of inhibitions to the pattern of a leap day every four years. Thus we add to correct for leap days that never occurred. ''p'' corrects for the lunar orbit not being fully describable in integer terms. The range of days considered for the full moon to determine Easter are 21 March (the day of the ecclesiastical equinox of spring) to 18 April—a 29-day range. However, in the mod 30 arithmetic of variable ''d'' and constant ''M'', both of which can have integer values in the range 0 to 29, the range is 30. Therefore, adjustments are made in critical cases. Once ''d'' is determined, this is the number of days to add to 22 March (the day after the earliest possible full moon allowed, which is coincident with the ecclesiastical equinox of spring) to obtain the date of the day after the full moon. So the first allowable date of Easter is , as Easter is to celebrate the Sunday after the ecclesiastical full moon; that is, if the full moon falls on Sunday 21 March, Easter is to be celebrated 7 days after, while if the full moon falls on Saturday 21 March, Easter is the following 22 March. The second part is finding ''e'', the additional offset days that must be added to the date offset ''d'' to make it arrive at a Sunday. Since the week has 7 days, the offset must be in the range 0 to 6 and determined by modulo 7 arithmetic. ''e'' is determined by calculating . These constants may seem strange at first, but are quite easily explainable if we remember that we operate under mod 7 arithmetic. To begin with, ensures that we take care of the fact that weekdays slide for each year. A normal year has 365 days, but , so 52 full weeks make up one day too little. Hence, each consecutive year, the weekday "slides one day forward", meaning if 6 May was a Wednesday one year, it is a Thursday the following year (disregarding leap years). Both ''b'' and ''c'' increase by one for an advancement of one year (disregarding modulo effects). The expression thus increases by 6 – but remember that this is the same as subtracting 1 mod 7. To subtract by 1 is exactly what is required for a normal year – since the weekday slips one day forward we should compensate one day less to arrive at the correct weekday (i.e. Sunday). For a leap year, ''b'' becomes 0 and 2''b'' thus is 0 instead of 8 – which under mod 7, is another subtraction by 1 – i.e., a total subtraction by 2, as the weekdays after the leap day that year slide forward by two days. The expression 6''d'' works the same way. Increasing ''d'' by some number ''y'' indicates that the full moon occurs y days later this year, and hence we should compensate y days less. Adding 6''d'' is mod 7 the same as subtracting ''d'', which is the desired operation. Thus, again, we do subtraction by adding under modulo arithmetic. In total, the variable ''e'' contains the step from the day after the day of the full moon to the nearest following Sunday, between 0 and 6 days ahead. The constant ''N'' provides the starting point for the calculations for each century and depends on where 1 January, year 1 was implicitly located when the Gregorian calendar was constructed. The expression can yield offsets in the range 0 to 35 pointing to possible Easter Sundays on 22 March to 26 April. For reasons of historical compatibility, all offsets of 35 and some of 34 are subtracted by 7, jumping one Sunday back to the day of the full moon (in effect using a negative ''e'' of −1). This means that 26 April is never Easter Sunday and that 19 April is overrepresented. These latter corrections are for historical reasons only and have nothing to do with the mathematical algorithm. The offset of 34 is adjusted if (and only if) ''d'' = 28 and ''d'' = 29 elsewhere in the 19-year cycle. Using the Gauss's Easter algorithm for years prior to 1583 is historically pointless since the Gregorian calendar was not utilised for determining Easter before that year. Using the algorithm far into the future is questionable, since we know nothing about how different churches will define Easter far ahead. Easter calculations are based on agreements and conventions, not on the actual celestial movements nor on indisputable facts of history.

Anonymous Gregorian algorithm

"A New York correspondent" submitted this algorithm for determining the Gregorian Easter to the journal ''

Nature Nature is an inherent character or constitution, particularly of the Ecosphere (planetary), ecosphere or the universe as a whole. In this general sense nature refers to the Scientific law, laws, elements and phenomenon, phenomena of the physic ...

'' in 1876. It has been reprinted many times, e.g., in 1877 by Samuel Butcher in ''The Ecclesiastical Calendar'', in 1916 by Arthur Downing in '' The Observatory'', in 1922 by H. Spencer Jones in ''General Astronomy'', in 1977 by the ''Journal of the British Astronomical Association'', in 1977 by ''The Old Farmer's Almanac'', in 1988 by Peter Duffett-Smith in '' Practical Astronomy with your Calculator'', and in 1991 by Jean Meeus in ''Astronomical Algorithms''. Because of the Meeus book citation, this is also called "Meeus/Jones/Butcher" algorithm: , 19 , , , , , - , , , , 61 , , , , , - , , , } , 4 , , , , , - , , , , 3 , , , , , - , , , } , 1 , , , , , - , , , } , 6 , , , , , - , , , , 10 , , , , , - , , , } , 15 , , , , , - , , , , 1 , , , , , - , , , , 1 , , , , - , , , } , 0 , , , , , - style="display:none", , , , , 125 , , , , , - , title="month", , , } , 4 , , , , , - , title="day of the month offset by one", , , , 1 , , , , , - !colspan=2, Gregorian Easter , 2 April 1961 , , , , In this algorithm, the variable ''n'' indicates the month of the year (either March for ''n'' = 3, or April for ''n'' = 4), while the day of the month is obtained as (''o'' + 1). In 1961 the ''New Scientist'' published a version of the ''Nature'' algorithm incorporating a few changes. The variable ''g'' was calculated using Gauss's 1816 correction, resulting in the elimination of variable ''f''. Some tidying results in the replacement of variable ''o'' (to which one must be added to obtain the date of Easter) with variable ''p'', which gives the date directly. , 6 , , , , , - , , , } , 0 , , , , , - , title="month", , , } , 4 , , , , , - , , , , , , , , , - , title="day of the month", , , , 2 , , , , , - !colspan=2, Gregorian Easter , 2 April 1961 , , , ,

Meeus's Julian algorithm

Jean Meeus, in his book ''Astronomical Algorithms'' (1991, p. 69), presents the following algorithm for calculating the Julian Easter on the Julian Calendar. To obtain the date of Eastern Orthodox Easter according to the Gregorian Calendar (used as the

civil calendar The civil calendar is the calendar, or possibly one of several calendars, used within a country for civil, official, or administrative purposes. The civil calendar is almost always used for general purposes by people and private organizations. Th ...

throughout most of the contemporary world), 13 days must be added to the Julian dates shown.

References

Notes

Citations

Sources

* . * * * * * * * * * In the fifth volume of Opera Mathematica, Mainz, 1612. Opera Mathematica of Christoph Clavius includes page images of the Six Canons and the ''Explicatio'' (Go to page: Roman Calendar of Gregory XIII). *Constantine the Great, Emperor (325): Letter to the bishops who did not attend the first Nicaean Council; from Eusebius' ''Vita Constantini''. English translations
''Documents from the First Council of Nicea'', "On the keeping of Easter" (near end)
an

* * * * *Dionysius Exiguus (525): ''Liber de Paschate''. On-line

an

* * *Eusebius of Caesarea, ''The History of the Church'', Translated by G. A. Williamson. Revised and edited with a new introduction by Andrew Louth. Penguin Books, London, 1989. *Gregory XIII (Pope) and the calendar reform committee (1581): the Papal Bull ''Inter Gravissimas'' and the Six Canons. On-line under

, with some parts of Clavius's ''Explicatio''. *. * * * * * * * * * * * * * * * * * * * *

External links

The Complete Works of Venerable Bede Vol. 6
(Contains ''De Temporibus'' and ''De Temporum Ratione''.)

* ttp://webspace.science.uu.nl/~gent0113/easter/eastercalculator.htm An Easter calculator with an extensive bibliography, and with useful links
Ephemeris site of the Bureau des Longitudes with an Easter calculator (valid between 325 and 2500)

A calendar page and calculator by Holger Oertel

* ttp://www.nabkal.de/gregkal.html An extensive calendar site and calendar and Easter calculator by Nikolaus A. Bär
Explanation of the Gregorian solar and lunar calendar, with improved procedures over the tabular method, by David Madore

* ttp://www.e-codices.unifr.ch/en/csg/0378/28/medium St. Gallen, Stiftsbibliothek, Codex Sangallensis 378 (11th century) p. 28. Contains the poem ''Nonae Aprilis norunt quinos''.
A simplified method for determining the date of Easter for all years 326 to 4099 by Ronald W. Mallen

Text of the Calendar (New Style) Act 1750, British Act of Parliament introducing the Gregorian Calendar
as amended to date. Contains tables for calculating Easter up until the year 8599. Contrast with the Act as passed.
Computuslat
A database of medieval manuscripts containing Latin computistical algorithms, texts, tables, diagrams and calendars. {{Time in religion and mythology Calendar algorithms Date of Easter Christian terminology Autumn equinox Spring equinox