- Revised Julian calendar
The Revised Julian calendar, also known as the Rectified Julian calendar, or, less formally, New calendar, is a calendar, originated in 1923, which effectively discontinued the 340 years of divergence between the naming of dates sanctioned by those Eastern Orthodox churches adopting it and the Gregorian calendar that has come to predominate worldwide. This calendar replaced the Ecclesiastical Calendar based on the Julian Calendar hitherto in use by all of the Eastern Orthodox Church. The Revised Julian Calendar temporarily aligned its dates with the Gregorian Calendar proclaimed in 1582 by Pope Gregory XIII for adoption by the Roman Catholic Church.
The new calendar was proposed for adoption by the Orthodox churches at a synod in Constantinople in May 1923. The synod, chaired by controversial Patriarch Meletius IV of Constantinople, and called Pan-Orthodox by its defenders, did not have representatives from the remaining Orthodox members of the original Pentarchy (the Patriarchate of Jerusalem, Antioch, and Alexandria) or from the largest Orthodox Church, the Russian Orthodox Church, then under persecution from the Bolsheviks, but only effective representation from the Patriarch of Constantinople and the Patriarch of Serbia.
This synod synchronized the new calendar with the Gregorian calendar by specifying that the next 1 October of the Julian calendar would be 14 October in the new calendar, thus dropping thirteen days. It then adopted a leap rule that differs from that of the Gregorian calendar: years divisible by four are leap years, except that years divisible by 100 are only leap years if dividing the year by 900 leaves a remainder of 200 or 600. This leap rule was proposed by the Serbian scientist Milutin Milanković, an astronomical delegate to the synod representing the Kingdom of Serbs, Croats and Slovenes. Milanković selected this rule because its mean year was within two seconds of the then current length of the mean tropical year. The present vernal equinox year, however, is about 12 seconds longer, in terms of mean solar days.
The synod also proposed the adoption of an astronomical rule for Easter: Easter was to be the Sunday after the midnight-to-midnight day at the meridian of the Church of the Holy Sepulchre in Jerusalem (35°13'47.2"E or UT+2h20m55s for the small dome) during which the first full moon after the vernal equinox occurs. Although the instant of the full moon must occur after the instant of the vernal equinox, it may occur on the same day. If the full moon occurs on a Sunday, Easter is the following Sunday. However, all Eastern Orthodox churches rejected this rule and continue to use the Julian calendar to determine the date of Easter (except for the Finnish Orthodox Church and the Estonian Orthodox Church which now use the Gregorian Easter).
The following are Gregorian minus Revised Julian date differences, calculated for the beginning of March in each century year, which is where differences arise or disappear, until 8000 AD. These are exact arithmetic calculations, not depending on any astronomy. A negative difference means that the proleptic Revised Julian calendar was behind the proleptic Gregorian calendar. A positive difference means that the Revised Julian calendar will be ahead of the Gregorian calendar, which will first occur on 1 March 2800:
Gregorian minus Revised Julian date differences Century
In 900 Julian years there are 900⁄4 = 225 leap days. The Revised Julian leap rule omits seven of nine century leap years, leaving 225−7 = 218 leap days per 900-year cycle. Thus the calendar mean year is 365+218⁄900 days, but this is actually a double-cycle that reduces to 365+109⁄450 = 365.242 days, or exactly 365 days 5 hours 48 minutes 48 seconds, which is exactly 24 seconds shorter than the Gregorian mean year of 365.2425 days, so in the long term the average rate at which the Revised Julian pulls ahead of the Gregorian calendar is 86400⁄24 = 3600 years per day.
The number of days per Revised Julian cycle = 900 × 365 + 218 = 328,718 days. Taking mod 7 leaves a remainder of 5, so like the Julian calendar the Revised Julian calendar cycle does not contain a whole number of weeks. Therefore, a full repetition of the Revised Julian leap cycle with respect to the seven-day day weekly cycle is seven times longer.
The epoch of the Julian calendar was on the Saturday before the Monday that was the epoch of the Gregorian calendar. In other words, Gregorian 1 January 1 AD = Julian 3 January 1 AD. The Revised Julian reform not only changed the leap rule but also made the epoch the same as that of the Gregorian calendar. This seems to have been carried out implicitly, and even scientific articles make no mention of it. Nevertheless, it is impossible to implement calendrical calculations and calendar date conversion software without appreciating this detail and taking the 2-day shift into account. If the original Julian calendar epoch is mistakenly used in such calculations then there is no way to reproduce the currently accepted dating of the Revised Julian calendar, which yields no difference between Gregorian and Revised Julian dates in the 21st century.
The following is a scatter plot of actual astronomical northward equinox moments as numerically integrated by SOLEX 11 using DE421 mode with extended (80-bit) floating point precision, high integration order (18th order), and forced solar mass loss ("forced" means taken into account at all times). SOLEX can automatically search for northern hemisphere spring equinox moments by finding when the solar declination crosses the celestial equator northward, and then it outputs that data as the Terrestrial Time day and fraction of day relative to 1 January 2000 at noon (J2000.0 epoch). The progressive tidal slowing of the Earth rotation rate was accounted for by subtracting ΔT as calculated by the Espenak-Meeus polynomial set recommended at the NASA Eclipses web site to obtain the J2000.0-relative Universal Time moments, which were then properly converted to Revised Julian dates and Jerusalem local apparent time, taking local apparent midnight as the beginning of each calendar day. The year range of the chart was limited to dates before the year 4400 AD — by then ΔT is expected to accumulate to about six hours, with an uncertainty of less than 2+1/2 hours.
The chart shows that the long-term equinox drift of the Revised Julian calendar is quite satisfactory, at least until 4400 AD. The medium-term wobble spans about two days because, like the Gregorian calendar, the leap years of the Revised Julian calendar are not smoothly spread: they occur mostly at intervals of four years but there are occasional eight-year gaps (at 7 out of 9 century years). Evidently each of the authorities responsible for the Gregorian and Revised Julian calendars, respectively, accepted a modest amount of medium-term equinox wobble for the sake of traditionally perceived leap rule mental arithmetic simplicity. Therefore the wobble is essentially a curiosity that is of no practical or ritual concern.
The new calendar has been adopted by the Orthodox churches of Constantinople, Alexandria, Antioch, Greece, Cyprus, Romania, Poland, and Bulgaria (the last in 1963), called the New calendarists. It has not been adopted by the Orthodox churches of Jerusalem, Russia, Serbia (including later on the resurrected, though uncanonical Macedonian Orthodox Church), Georgia, and the Greek Old Calendarists. Although Milanković stated that the Russian Orthodox Church adopted the new calendar in 1923, the present church continues to use the Julian calendar for both its fixed festivals and for Easter. A solution to this conundrum is to hypothesize that it was accepted only by the short-lived schismatic Renovationist Church, which had seized church buildings with the support of the Soviet government while Patriarch Tikhon was under house arrest. After his release, on 15 July 1923, he declared that all Renovationist decrees were without grace, presumably including its acceptance of the new calendar.
The basic justification for the new calendar is the known errors of the Julian calendar, which will in the course of time lead to a situation in which those following the Julian calendar will be reckoning the month of December (and the feast of Christ's Nativity) during the heat of summer, August and its feasts during the deep cold of winter, Pascha during the autumn season, and the November feasts in the springtime. This would conflict with the Church's historic practice of celebrating Christ's birth on 25 December, a date chosen for a number of reasons. One of the reasons mentioned by Bennet is the time of the winter solstice, when the days begin to lengthen again as the physical sun makes its reappearance, along with the fact that Christ has traditionally been recognized by Christians as the metaphorical and spiritual sun who fulfills Malachi's prophetic words: "the sun of righteousness will shine with healing in its wings" (Malachi 4:2). The identification, based on this prophecy, of Jesus Christ as the "sun of righteousness" is found many times in writings of the early Church fathers and follows from many New Testament references linking Jesus with imagery of sun and light.
The defenders of the new calendar do not regard the Julian calendar as having any particular divine sanction (for more on this, see below); rather, they view the Julian calendar as a device of human technology, and thus subject to improvement or replacement just as many other devices of technology that were in use at the dawn of the Church have been replaced with newer forms of technology.
Supporters of the new calendar can also point to certain pastoral problems that are resolved by its adoption.
(1) Parishes observing the Julian calendar are faced with the problem that parishioners are supposed to continue fasting throughout western Christmas and New Year, seasons when their families and friends are likely to be feasting and celebrating New Year's, often with parties, use of liquor, etc. This situation presents obvious temptations, which are eliminated when the new calendar is adopted.
(2) Another pastoral problem is the tendency of some local American media to focus attention each year on the 7 January (N.S.) / 25 December (O.S.) celebration of Christmas, even in localities where most Orthodox parishes are following the new calendar. So too, in all likelihood, do certain non-Orthodox churches profit from the Orthodox remaining Old Style, since the 7 January observance of Christmas among the Orthodox tends to focus attention on ethnic identifications of the feast, rather than on its Christian, dogmatic significance; which, in turn, tends to foster the impression in the public mind that for the Orthodox, the feast of Christ's Nativity is centered on the observance of the Julian date of that feast, rather than on the commemoration of Christ's birth. Such a focus appears to the defenders of the Revised Julian Calendar and to many non-Orthodox as well, as a practice that is charming and quaint, but also anachronistic, unscientific and hence ultimately unreasonable and even cultish.
(3) Some Orthodox themselves may unwittingly reinforce this impression by ignorance of their own faith and by a consequential exclusive, or excessive, focus on the calendar issue: it has been observed, anecdotally, that some Russians cannot cite any difference in belief or practice between their faith and the faith of western Christians, except for the 13-day calendar difference.
Against the new calendar, the argument is made that inasmuch as the use of the Julian calendar was implicit in the decision of the First Ecumenical Council at Nicaea (325), no authority less than an Ecumenical Council may change this decision. However, the fact is that that Council made no decision or decree at all concerning the Julian Calendar. Its silence constituted an implicit acceptance not of the Julian Calendar, but of the civil calendar, which happened to be, at that time, the Julian calendar (the explicit decision of Nicaea being concerned, rather, with the date of Easter). By virtue of this, defenders of the new calendar argue that no decision by an Ecumenical Council was or is necessary today in order to revise (not abandon) the Julian calendar; and further, that by making the revision, the Church stays with the spirit of Nicaea I by keeping with the civil calendar in all its essentials — while conversely, failure to keep with the civil calendar could be seen as a departure from the spirit of Nicaea I in this respect. Lastly, it is argued that since the adoption of the new calendar evidently involves no change in or departure from the theological or the ethical teachings of Orthodox Christianity, but rather amounts to a merely disciplinary or administrative change — a clock correction of sorts — the authority to enact that change falls within the competency of contemporary, local episcopal authority. Implicit acceptance of this line of reasoning, or something very close to it, underlies the decision to adopt the new calendar by those Orthodox churches which have done so.
It follows that, in general, the defenders of the new calendar hold the view that in localities where the Church's episcopal authority has elected to adopt the new calendar, but where some have broken communion with those implementing this change, it is those who have broken communion who have in fact introduced the disunity, rather than the new calendar itself or those who have adopted it — although most would agree that attempts at various times to mandate the use of the new calendar through compulsion, have magnified the disunity.
To the objection that the new calendar has created problems by adjusting only the fixed calendar, while leaving all of the commemorations on the moveable cycle on the original Julian calendar, the obvious answer, of course, is that the 1923 Synod, which adopted the new calendar, did in fact change the moveable calendar as well, and that calendar problems introduced as a result of the adoption of the (fixed) new calendar alone, would not have existed had the corrections to the moveable calendar also been implemented.
According to the defenders of the new calendar, the argument that the 25 December (N.S.) observance of Christmas is a purely secular observance and is therefore an unsuitable time for Orthodox Christians to celebrate Christ's Nativity, is plainly inaccurate, since the 25 December observances of Christ's birth among western Christians (and today, among many Orthodox Christians) obviously occur overwhelmingly in places of worship and involve hymns, prayers, scripture readings, religious dramas, liturgical concerts, and the like. Defenders of the new calendar further note that, to the extent that 25 December is a secular observance in the western world, 7 January (i.e. 25 December O.S.) appears to be becoming one as well, in Orthodox countries that continue to follow the Old Calendar. In Russia, for example, 7 January is no longer a spiritual holiday for Orthodox Christians alone, but has now become a national (hence secular) holiday for all Russians, including non-Orthodox Christians, people of other religions, and nonbelievers. Where this will lead in the end remains to be seen.
Among other arguments made by the defenders of the new calendar for their view, are those made on the basis of truth (notwithstanding that the detractors of that calendar make the claim that the Old Style date, 7 January / 25 December, is the true celebration of Christ's Nativity). Arguments from truth can take two forms: (1) If a calendar is a system for reckoning time based on the motions of astronomical bodies — specifically the movements of Sun and Moon, in the case of the church calendar — and if precision or accuracy is understood as one aspect of truth, then a calendar that is more accurate and precise with respect to the motions of those bodies must be regarded as truer than one which is less precise. In this regard, some of those who champion the Old Calendar as truth (rather than for pastoral reasons, as seems to be the case with the national churches that adhere to it) may appear, to those following the new calendar, as the defenders of a fiction. (2) Some defenders of the new calendar argue that the celebration, in any way or form, of two feasts of Christ's Nativity within the same liturgical year is not possible, since according to the faith there is only one celebration of that feast in a given year. On this basis, they argue that those who prefer to observe a "secular" feast of the Nativity on 25 December and a "religious" one on 7 January, err in respect of the truth that there is but one feast of the Nativity each year.
While the new calendar has been adopted by many of the smaller national churches, a majority of Orthodox Christians continue to adhere to the traditional Julian calendar, and there has been much acrimony between the two parties over the decades since the change, leading sometimes even to violence, especially in Greece.
Critics see the change in calendar as an unwarranted innovation, influenced by Western society. They say that no sound theological reason has been given for changing the calendar, that the only reasons advanced are social. The proposal for change was introduced by a Patriarch whose canonical status has been disputed and who was a Freemason.
The argument is also made that since the use of the Julian calendar was implicit in the decision of the First Ecumenical Council at Nicaea (325) which standardized the calculation of the date of Pascha (Easter), no authority less than an Ecumenical Council may change it. The adoption of a new calendar has broken the unity of the church, undoing the whole purpose of the council of Nicaea, so once again, "on the same day some should be fasting whilst others are seated at a banquet."
Liturgical objections to the new calendar stem from the fact that it adjusts only those liturgical celebrations that occur on fixed calendar dates, leaving all of the commemorations on the moveable cycle on the original Julian calendar. This upsets the harmony and balance of the liturgical year. (This would not have been a problem if the recommendations of the 1923 synod to use an astronomical rule to reckon the date of Easter, as outlined above, had not been rejected.) This disruption is most noticeable during Great Lent. Certain feast days are designed to fall during Lent, such as the feast of the Forty Martyrs of Sebaste. The Feast of the Annunciation is also intended to fall either before Pascha or during Bright Week. Sometimes, Annunciation will fall on the day of Pascha itself, a very special concurrence known as Kyrio-Pascha, with special liturgical practices appointed for such an occurrence. However, under the new calendar, Kyrio-Pascha becomes an impossibility. The Apostles' Fast displays the most difficult aspect of the new calendar. The fast begins on the moveable cycle and ends on the fixed date of 29 June; since the new calendar is 13 days ahead of the traditional Julian calendar, the Apostles' Fast is 13 days shorter for those who follow the new calendar, and some years it is completely abrogated. Furthermore, critics of the new calendar point out the advantage to celebrating Nativity separately from the secular observances of Christmas and New Year, which are associated with partying and alcohol consumption.
Critics also point out that proponents of the new calendar tend to use worldly rather than spiritual justification for changing the calendar: wanting to "party with everyone else" at Christmas; concern that the gradual shift in the Julian calendar will somehow negatively affect the celebration of feasts that are linked to the seasons of the year. However, opponents counter that the seasons are reversed in the southern hemisphere, where the liturgical celebrations are no less valid. The validity of this argument is questionable, since the feasts of the Orthodox Church were not changed no matter where they were celebrated, and Orthodox services were held in the southern hemisphere with little issue centuries before the introduction of the new calendar.
Proponents also argue that the new calendar is somehow more "scientific", but opponents argue that science is not the primary concern of the Church; rather, the Church is concerned with other-worldliness, with being "in the world, but not of it", fixing the attention of the faithful on eternity. Scientifically speaking, neither the Gregorian calendar nor the new calendar is absolutely precise. This is because the solar year cannot be evenly divided into 24 hour segments. So any public calendar is imprecise; it is simply an agreed-upon designation of days.
From a spiritual perspective, Old Calendarists also point to a number of miraculous occurrences which occur on the Old Calendar exclusively, such as the "descent of the cloud on the mount" on the feast of the Transfiguration. After the calendar change was instituted, the followers of the Old Calendar in Greece apparently witnessed the appearance of a cross in the sky, visible to thousands on the feast of the Exaltation of the Holy Cross, 1925, of which eyewitness accounts were recorded.
For such special events, if the original Julian date and year is known then the option always exists to calculate what was the proleptic Revised Julian date of that event and then observe its anniversary on that day, if that could be socially and ritually accepted.
Revised Julian calendrical calculations
The calendrical arithmetic discussed here is adapted from Gregorian and Julian calendar arithmetic published by Dershowitz and Reingold, although those authors explicitly ignored the Revised Julian calendar. Their book, which will be referred to hereinafter as "CC3", should be consulted for methods to handle BC dates and the traditional omission of a year zero, both of which will be ignored here. They define the MOD operator as x MOD y = x − y × floor(x / y), because that expression is valid for negative and floating point operands, returning the remainder from dividing x by y while discarding the quotient. Expressions like floor(x / y) return the quotient from dividing x by y while discarding the remainder.
isLeapYear = (year MOD 4 = 0)
IF isLeapYear THEN
- IF year MOD 100 = 0 THEN
- Century = (year / 100) MOD 9
- isLeapYear = (Century=2) OR (Century=6)
- END IF
Calendrical calculations are made consistent and straightforward for arithmetic operations if dates are first converted to an ordinal number of days relative to an agreed-upon epoch, in this case the Revised Julian epoch, which was the same as the Gregorian epoch. To find the difference between any two Revised Julian dates, convert both to ordinal day counts and simply subtract. To find a past or future date, convert a given date to an ordinal day count, subtract or add the desired number of days, then convert the result to a Revised Julian date.
The arithmetic given here will not "crash" if an invalid date is given. To verify that a given date is a valid Revised Julian date, convert it to an ordinal day count and then back to a Revised Julian date — if the final date differs from the given date then the given date is invalid. This method should also be used to validate any implementation of calendrical arithmetic, by iteratively checking thousands of random and sequential dates for such errors.
To convert a Revised Julian date to any other calendar, first convert it to an ordinal day count, and then all that is needed is a function to convert the ordinal days count to that calendar. To convert a date from any other calendar to a Revised Julian date, first convert that calendar date to an ordinal day count, then convert ordinal days to the Revised Julian date.
The following constant defined midnight at the start of Revised Julian date Monday, 1 January 1 AD as the beginning of the first ordinal day. This moment was Julian Day number 1721425.5.
- RJepoch = 1
CC3 outlines functions for Gregorian and Julian calendar conversions, as well as many other calendars, always calculating in terms of the ordinal day number, which they call the "fixed date" or rata die (RD), assigning the number 1 to the Gregorian calendar epoch. The arithmetic herein, by using the same ordinal day numbering epoch, is fully compatible with all CC3 functions for calendrical calculations and date inter-conversions.
You can assign a different integer to the Revised Julian epoch, for the purpose of numbering ordinal days relative to some other epoch, but if you do so then take the epoch difference into account when using any CC3 calendar functions and when converting an ordinal day number to a weekday number.
Optionally the ordinal day number can include a fractional component to represent the time as the elapsed fraction of a day. The ordinal day number of the J2000 moment (1 January 2000 noon) was 730120.5.
Revised Julian to Fixed Days
Convert a year, month, and day to the corresponding fixed day number:
- PriorYear = year − 1
- FixedDays = RJepoch + 365 × PriorYear + floor(PriorYear / 4) + floor((367 × month − 362) / 12) + day − 1
If month is after February then subtract 1 day for a leap year or subtract 2 days for a common year:
- IF month > 2 THEN
- IF isLeapYear(year) THEN
- FixedDays = FixedDays − 1
- FixedDays = FixedDays − 2
- END IF
- IF isLeapYear(year) THEN
- END IF
Finally subtract a day for each prior century year (most of which are non-leap) and then add back in the number of prior century leap years:
- PriorCenturies = floor(PriorYear / 100)
- FixedDays = FixedDays − PriorCenturies + floor((2 × PriorCenturies + 6) / 9)
Fixed days to Revised Julian
Convert an ordinal day number to the corresponding Revised Julian year, month, and day, starting by removing any fractional time-of-day portion:
- Days = floor(FixedDays) − RJepoch + 1
- PriorCenturies = floor(Days / 36524)
- RemainingDays = Days − 36524 × PriorCenturies - floor((2 × PriorCenturies + 6) / 9)
- PriorSubcycles = floor(RemainingDays / 1461)
- RemainingDays = RemainingDays MOD 1461
- PriorSubcycleYears = floor(RemainingDays / 365)
- year = 100 × PriorCenturies + 4 × PriorSubcycles + PriorSubcycleYears
- RemainingDays = RemainingDays MOD 365
- IF RemainingDays = 0 THEN
- This is either the 365th day of a common year, or the 365th or 366th day of a leap year. Either way, we have to decrement the year because we went one year too far:
- year = year − 1
- IF isLeapYear(year) AND PriorSubcycles=0 THEN RemainingDays=366 ELSE RemainingDays=365
- END IF
- PriorDays = RemainingDays − 1
- IF isLeapYear(year) THEN correction = 1 ELSE correction = 0
- IF PriorDays < (31+28+correction) THEN correction = 0 ELSE correction = 2 − correction
- Month = floor((12 × (PriorDays + correction) + 373) / 367)
Finally, calculate the day number within the month by subtracting the Fixed days count for the start of the month from the originally given Fixed days count, and then add one day:
- Day = FixedDays - RevisedJulianToFixed(year, month, 1) + 1
Fixed days to weekday number
Convert the ordinal number of days since the Revised Julian epoch to a weekday number (Sunday=1 through Saturday = 7):
- WeekdayNumber = (floor(FixedDays) − RJepoch + 1) MOD 7 + 1
Don't be tempted to omit subtracting the RJepoch just because it is offset by adding +1. As written, this expression is robust even if you assign a value other than one to the epoch.
- ^ Encyclopedia Britannica On-line, http://www.britannica.com/EBchecked/topic/245469/Gregorian-calendar (Accessed 20 April 2010)
- ^ Hieromonk Cassian, A Scientific Examination of the Orthodox Church Calendar, Center for Traditionalist Orthodox Studies, 1998, p.51-52,ISBN 0-911165-31-2.
- ^ M. Milankovitch, "Das Ende des julianischen Kalenders und der neue Kalender der orientalischen Kirchen", Astronomische Nachrichten 220/5279 (1924) 379–384.
- ^ a b Miriam Nancy Shields, "The new calendar of the Eastern churches", Popular Astronomy 32 (1924) 407–411 (page 411). This is a translation of the paper by Milankovitch in Astronomische Nachrichten.
- ^ M.S. Dimitrijević and E. Theodossiou, "The calendar of the Greek Orthodox Church", Astronomical & Astrophysical Transactions, 21:1, 145-147, 2002.
- ^ Aldo Vitagliano. "Numerical integration for the real time production of fundamental ephemerides over a wide time span.", Celestial Mechanics and Dynamical Astronomy 1997; 66: 293–308.
- ^ The SOLEX home page.
- ^ W. M. Folkner, J. G. Williams, D. H. Boggs (2008). The Planetary and Lunar Ephemeris DE 421 Jet Propulsion Laboratory, California Institute of Technology, Memorandum IOM 343R-08-003, 31-March 2008
- ^ Peter D. Noerdlinger. "Solar Mass Loss, the Astronomical Unit, and the Scale of the Solar System." arXiv:0801.3807v1 [astro-ph].
- ^ NASA Eclipses Delta T web site, giving the Espenak-Meeus polynomial expressions for Delta T.
- ^ Uncertainty in Delta T (ΔT).
- ^ Choosing the Date of Christmas: Why is Christmas Celebrated on December 25? by David Bennett.
- ^ Jesus as the Sun Throughout History, by D.M. Murdock/Acharya S.
- ^ Ibid.
- ^ The Orthodox Church Calendar: In Defense of the Julian Calendar, Holy Trinity Monastery, Jordanville, NY, 1996 p.11, ISBN 0-88465-065-062-6
- ^ ΕΠΙΦΑΝΕΙΣ ΕΛΛΗΝΕΣ ΕΛΕΥΘΕΡΟΤΕΚΤΟΝΕΣ (Greek), Grand Lodge of Greece Website, Accessed 16 Feb 2010. Contains the name of the Patriarch in question Meletios Metaxakis, "Alexandrian and Ecumenical Patriarch," listed on its website.
- ^ Meletios Metaxakis
- ^ Eusebius, Vita Const., Lib. iii., 18–20. On the Keeping of Easter. Accessed 4 June 2007.
- ^ The Appearance of the Sign of the Cross Near Athens in 1925
- ^ Nachum Dershowitz, Edward M. Reingold. Calendrical Calculations, Third Edition. Page 47, footnote 3. Cambridge University Press, 2008.
- ^ ibid, page 18, equation 1.15.
- ^ For example, see "alt-fixed-from-gregorian" in erratum 106, equation 2.25 in Errata for "Calendrical Calculations: The Millennium Edition".
- The Calendar of the Orthodox Church by Dr. Lewis J. Patsavos, Ph.D.
- The "Revised" Julian Calendar: Memorandum of Explanation by the Holy Synod (Orthodox Church in America)
- Liturgical Havoc Wreaked by the "New Julian" Calendar by Hieromonk Cassian
- The Essence of the Church Calendar
- On the Question of the "Revised Julian Calendar" by Father George Lardas
- Freeware calendar date conversion and astronomy events calculator for Windows. Interconverts dates of Revised Julian, Julian, Gregorian and several other calendars.
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- IF year MOD 100 = 0 THEN
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