A 'lunisolar calendar' is a
calendar in many
cultures whose date indicates both the
moon phase and the time of the solar
year. If the solar year is defined as a
tropical year then a lunisolar calendar will give an indication of the
season; if it is taken as a
sidereal year then the calendar will predict the
constellation near which the
full moon may occur. Usually there is an additional requirement that the year has a whole number of months, in which case most years have 12 months but every second or third year has 13 months.
Examples
The
Buddhist,
Hebrew,
Hindu lunisolar,
Tibetan calendars,
Chinese calendar used alone until
1912 (and then used along with the
Gregorian calendar) and
Korean calendar (used alone until 1894 and since used along with the
Gregorian calendar) are all lunisolar, as was the
Japanese calendar until
1873, the
pre-Islamic calendar, the republican
Roman calendar until
45 BC (in fact earlier, because the synchronization to the moon was lost as well as the synchronization to the sun), the first century Gaulish
Coligny calendar and the
second millennium BC Babylonian calendar. The Chinese, Coligny and Hebrew lunisolar calendars track the tropical year whereas the Buddhist and Hindu lunisolar calendars track the sidereal year. Therefore the first three give an idea of the seasons whereas the last two give an idea of the position among the constellations of the full moon. The Tibetan calendar was influenced by both the Chinese and Hindu calendars. The English also used a lunisolar calendar before their conversion to Christianity .
The
Islamic calendar is a
lunar, but not lunisolar calendar because its date is not related to the sun. The
Julian and
Gregorian Calendars are
solar, not lunisolar, because their dates do not indicate the moon phase — however, without realising it, most Christians do use a lunisolar calendar in the determination of
Easter.
There are some lunisolar
calendar reform proposals: One is the
Hermetic Lunar Week Calendar which normally consists of 12 lunar months and a leap month every 2 or 3 years, and with a year that always starts near the
vernal equinox. Another is the
Simple Lunisolar Calendar, whose year always begins between Gregorian
December 3 and
January 1. Also there is the
Meyer-Palmen Solilunar Calendar whose year always begins near the vernal equinox by using a 2498258 days in 84599 months in a 6840-year-cycle rule.
Determining leap months
To determine when an
embolismic month needs to be inserted, some calendars rely on direct observations of the state of vegetation, while others compare the
ecliptic longitude of the sun and the
phase of the moon.
On the other hand, in arithmetical lunisolar calendars, an integral number of
synodic months is fitted into some integral number of years by a fixed rule. To construct such a calendar, the average length of the
tropical year is divided by the average length of the synodic month, which gives the number of average synodic months in a year as:
12.368266......
Continued fractions of this decimal value give optimal approximations for this value. So in the list below, after the number of synodic months listed in the numerator, an integer number of tropical years as listed in the denominator have been completed:
12 / 1 = 12 (error = -0.368266... synodic months/year)
25 / 2 = 12.5 (error = 0.131734... synodic months/year)
37 / 3 = 12.333333... (error = 0.034933... synodic months/year)
99 / 8 = 12.375 (error = 0.006734... synodic months/year)
136 / 11 = 12.363636... (error = -0.004630... synodic months/year)
235 / 19 = 12.368421... (error = 0.000155... synodic months/year)
4131 / 334 = 12.368263... (error = -0.000003... synodic months/year)
The 8-year cycle (99 synodic months, including 3 embolismic months) was used in the ancient Athenian calendar. The 8-year cycle was also used in early third-century
Easter calculations (or old ''Computus'') in Rome and Alexandria.
The 19-year cycle (235 synodic months, including 7 embolismic months) is the classic
Metonic cycle, which is used in most arithmetical lunisolar calendars. It is a combination of the 8- and 11-year period, and whenever the error of the 19-year approximation has built up to a full day, a cycle can be truncated to 8 or 11 years, after which 19-year cycles can start anew.
Meton's cycle had an integer number of days, although ''Metonic cycle'' often means its use without an integer number of days. It was adapted to a mean year of 365.25 days by means of the 4×19 year
Callipic cycle (used in the Easter calculations of the Julian calendar).
Rome used an 84-year cycle from the late third century until
457.
Early Christians in Britain and Ireland also used an 84-year cycle until the
Synod of Whitby in
664. The 84-year cycle is equivalent to a Callipic 4×19-year cycle (including 4×7 embolismic months) plus an 8-year cycle (including 3 embolismic months) and so has a total of 1039 synodic months (including 31 embolismic months). This gives an average of 12.369047... synodic months per year (with error=0.011123... synodic months/year, a less good approximation than the regular 8-year Athenian cycle or the Metonic 19-year cycle).
The last listed approximation with the 334-years cycle (4131 synodic months, including 123 embolismic months) is very sensitive to the adopted values for the lunation and year, especially the year. There are different possible definitions of the year, other approximations may be more accurate. For example (4366/353) is more accurate for a vernal equinox
tropical year and (1979/160) is more accurate for a
sidereal year.
Calculating a "leap month"
A rough idea of the frequency of the intercalary or leap month in all lunisolar calendars can be obtained by the following calculation, using approximate lengths of months and years in days:
★ Year: 365.25, Month: 29.53
★ 365.25/(12 × 29.53) = 1.0307
★ 1/0.0307 = 32.57 common months between leap months
★ 32.57/12 − 1 = 1.7 common years between leap years
A representative sequence of common and leap years is ccLccLcLccLccLccLcL, which is the classic nineteen-year
Metonic cycle. The Buddhist and Hebrew calendars restrict the leap month to a single month of the year, so the number of common months between leap months is usually 36 months but occasionally only 24 months elapse. The Chinese and Hindu lunisolar calendars allow the leap month to occur after or before (respectively) any month but use the true motion of the
sun, so their leap months do not usually occur within a couple of months of
perihelion, when the apparent speed of the sun along the
ecliptic is fastest (now about 3 January). This increases the usual number of common months between leap months to roughly 34 months when a doublet of common years occurs while reducing the number to about 29 months when only a common singleton occurs.
References
★
Introduction to Calendars, US Naval Observatory, Astronomical Applications Department.
See also
★
Month
★
Solar calendar
★
Lunar calendar
External links
★
Panchangam for your city ''Panchangam for your city based on High Precision Drika Ganita.''
★
Perpetual Chinese Lunar Program ''The Chinese calendar is one of the oldest lunisolar calendars.''
★
Lunisolar Calendar ''Page contains a useful description of the difference between lunar calendars and lunisolar calendars.''
★
A simple lunisolar calendar ''As the name suggests, this is a simple example of a lunisolar calendar that utilises the Gregorian calendar. A discussion of issues that affect accuracy is included.''
★
Calendar studies ''A general discussion of calendar systems including two examples of lunisolar calendars.''
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