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Information about Month

For the Egyptian hawk-god, see .


The month is a unit of time, used with calendars, which is approximately as extensive as some natural period related to the motion of the Moon. The traditional concept arose with the cycle of moon phases; such months (lunations) are synodic months and last approximately 29.53 days. From excavated tally sticks, researchers have deduced that people counted days in relation to the Moon's phases as early as the Paleolithic age. Synodic months are still the basis of many calendars today.

Astronomical background

The motion of the Moon in its orbit is very complicated and its period is not constant. Moreover, many cultures (most notably those using the ancient Hebrew (Jewish) calendar and the Islamic calendar) start a month with the first appearance of the thin crescent of the new moon after sunset over the western horizon. The date and time of this actual observation depends on the exact geographical longitude as well as latitude, atmospheric conditions, the visual acuity of the observers, etc. Therefore the beginning and lengths of months in these calendars can not be accurately predicted. Most Jews currently follow a precalculated calendar, but the Karaites rely on actual moon observations.

Sidereal month

The period of the Moon's orbit as defined with respect to the celestial sphere is known as a sidereal month because it is the time it takes the Moon to return to a given position among the stars (Latin: sidus): 27.321661 days (27 d 7 h 43 min 11.5 s). This type of month has been observed among cultures in the Middle East, India, and China in the following way: they divided the sky into 27 or 28 lunar mansions, defined by asterisms (apparent groups of stars), one for each day of the sidereal month.

Tropical month

It is customary to specify positions of celestial bodies with respect to the vernal equinox. Because of precession, this point moves back slowly along the ecliptic. Therefore it takes the Moon less time to return to an ecliptic longitude of zero than to the same point amidst the fixed stars: 27.321582 days (27 d 7 h 43 min 4.7 s). This slightly shorter period is known as tropical month; cf. the analogous tropical year of the Sun.

Anomalistic month

Like all orbits, the Moon's orbit is an ellipse rather than a circle. However, the orientation (as well as the shape) of this orbit is not fixed. In particular, the position of the extreme points (the line of the apsides: perigee and apogee), makes a full circle (lunar precession) in about nine years. It takes the Moon longer to return to the same apsis because it moved ahead during one revolution. This longer period is called the anomalistic month, and has an average length of 27.554551 days (27 d 13 h 18 min 33.2 s). The apparent diameter of the Moon varies with this period, and therefore this type has some relevance for the prediction of eclipses (see Saros), whose extent, duration, and appearance (whether total or annular) depend on the exact apparent diameter of the Moon. The apparent diameter of the full moon varies with the full moon cycle which is the beat period of the synodic and anomalistic month, and also the period after which the apsides point to the Sun again.

Draconic month

Also called the nodical month. The orbit of the moon lies in a plane that is tilted with respect to the plane of the ecliptic: it has an inclination of about five degrees. The line of intersection of these planes defines two points on the celestial sphere: the ascending node, when the moon's path crosses the ecliptic as the moon moves into the northern hemisphere, and descending node when the moon's path crosses the ecliptic as the moon moves into the southern hemisphere. The draconic or nodical month is the average interval between two successive transits of the moon through its ascending node. Due to the sun's gravitational pull on the moon, the moon's orbit gradually rotates westward on its axis, which means the nodes gradually rotate around the earth. As a result, the time it takes the moon to return to the same node is shorter than a sidereal month. It lasts about 27-1/5 days (27.212220 days or 27 d 5 h 5 min 35.8 s). The plane of the moon's orbit precesses over a full circle in about 18.6 years.

Because the moon's orbit is inclined with respect to the ecliptic, the sun, moon, and earth are in line only when the moon is at one of the nodes. Whenever this happens a solar or lunar eclipse is possible. The name "draconic" refers to a mythical dragon, said to live in the nodes and eat the sun or moon during an eclipse.

Synodic month

This is the average period of the Moon's revolution with respect to the sun. The synodic month is responsible for the moon phases because the Moon's appearance depends on the position of the Moon with respect to the Sun as seen from the Earth. While the moon is orbiting the earth, the Earth is progressing in its orbit around the Sun. This means that after completing a sidereal month the Moon must move a little farther to reach the new position of the Earth with respect to the Sun. This longer period is called the synodic month from the Greek syn hodô (σὺν ὁδῴ), meaning "with the way [of the sun]". Because of the perturbations of the orbits of the Earth and Moon, the actual time between lunations may range from about 29.27 to about 29.83 days. The long-term average duration is 29.530588 days (29 d 12 h 44 min 2.8 s). The synodic month is used in the Metonic cycle.

Month lengths

Here is a list of the average length of the various astronomical lunar months [1]. These are not constant, so a first-order (linear) approximation of the secular change is provided:

Valid for the epoch J2000.0 (1 Jan. 2000 12:00 TT):

sidereal month27.321661547 + 0.000000001857 × y days
tropical month27.321582241 + 0.000000001506 × y days
anomalistic month27.554549878 − 0.000000010390 × y days
draconic month27.212220817 + 0.000000003833 × y days
synodic month29.530588853 + 0.000000002162 × y days


Note: time expressed in Ephemeris Time (more precisely Terrestrial Time) with days of 86,400 SI seconds. y is years since the epoch (2000), expressed in Julian years of 365.25 days. Note that for calendrical calculations, one would probably use days measured in the time scale of Universal Time, which follows the somewhat unpredictable rotation of the Earth, and progressively accumulates a difference with ephemeris time called ΔT.

Calendrical consequences

For more details on this topic, see lunar calendar and lunisolar calendar.


At the simplest level, all lunar calendars are based on the approximation that 2 lunations last 59 days: a 30 day full month followed by a 29 day hollow month — but this is only marginally accurate and quickly needs correction by using larger cycles, or the equivalent of leap days.

Second, the synodic month does not fit easily into the year, which makes constructing accurate, rule-based lunisolar calendars difficult. The most common solution to this problem is the Metonic cycle, which takes advantage of the fact that 235 lunations are approximately 19 tropical years (which add up to not quite 6940 days). However, a Metonic calendar (such as the Hebrew calendar) will drift against the seasons by about 1 day every 200 years.

The problems of creating reliable lunar calendars may explain why solar calendars, having months which no longer relate to the phase of the moon, and being based only on the motion of the sun against the sky, have generally replaced lunar calendars for civil use in most societies.

Months in various calendars

Julian and Gregorian calendars

The Gregorian calendar, like the Julian calendar before it, has twelve months:
  1. January, 31 days
  2. February, 28 days, 29 in leap years, or 30 on certain occasions in related calendars
  3. March, 31 days
  4. April, 30 days
  5. May, 31 days
  6. June, 30 days
  7. July, 31 days
  8. August, 31 days
  9. September, 30 days
  10. October, 31 days
  11. November, 30 days
  12. December, 31 days


One of Wikipedia's sister projects, Wiktionary, provides translations of each of the Gregorian/Julian calendar months into a dozen or more languages. Month-by-month links are provided here: , , , , , , , , , , , .


The average month in the Gregorian calendar has a length of 30.4167 days or 4.345 weeks in a non-leap year and 30.5 days or 4.357 weeks in a leap year.

Months existing in the Roman calendar in the past include: The famous mnemonic Thirty days hath September is the most common way of teaching the lengths of the months in the English-speaking world.

Enlarge picture
On top of the knuckles (yellow): 31 days
Between the knuckles (blue): 30 days
February (red) has 28 or 29 days.
The knuckles of the four fingers of one's hand and the spaces between them can be used to remember the lengths of the months. By making a fist, each month will be listed as one proceeds across the hand. All months landing on a knuckle are 31 days long and those landing between them are not. When the knuckle of the index finger is reached (July), go back to the first knuckle (or over to the first knuckle on the other fist, held next to the first) and continue with August. This physical mnemonic has been taught to primary school students for many decades.[2][3][4][5]

Calends, nones, and ides

The ides occur on the thirteenth day in eight of the months, but in March, May, July, and October, they occur on the fifteenth. The nones always occur 8 days before the ides, i.e., on the fifth or the seventh. The calends are always the first day of the month.

French Republican calendar

This calendar was proposed during the French Revolution, and used by the French government for about twelve years from late 1793. There were twelve months of 30 days each, grouped into three ten-day weeks called décades. The five or six extra days needed to approximate the tropical year were placed after the months at the end of each year. A period of four years ending on a leap day was to be called a Franciade. It began at the autumn equinox:
  • Autumn:
  1. Vendémiaire
  2. Brumaire
  3. Frimaire
  • Winter:
  1. Nivôse
  2. Pluviôse
  3. Ventôse
  • Spring:
  1. Germinal
  2. Floréal
  3. Prairial
  • Summer:
  1. Messidor
  2. Thermidor
  3. Fructidor

Islamic calendar

There are also twelve months in the Islamic calendar. They are named as follows:
  1. Muharram ul Haram (or shortened to Muharram) محرّ?
  2. Safar صف?
  3. Rabi`-ul-Awwal (Rabi' I) ربيع الأو?
  4. Rabi`-ul-Akhir (or Rabi` al-Tיhaany) (Rabi' II) ربيع الآخر أو ربيع الثان?
  5. Jumaada-ul-Awwal (Jumaada I) جمادى الأو?
  6. Jumaada-ul-Akhir (or Jumaada al-THaany) (Jumaada II) جمادى الآخر أو جمادى الثان?
  7. Rajab رج?
  8. Sha'aban شعبا?
  9. Ramadhan رمضا?
  10. Shawwal شوّا?
  11. Dhul Qadah (or Thw al-Qi`dah) ذو القعدة
  12. Dhul Hijja (or Thw al-Hijjah) ذو الحج?

Hebrew Calendar

The Hebrew calendar has 12 or 13 months.
  1. Nisan, 30 days ניס?
  2. Iyyar, 29 days איי?
  3. Sivan, 30 days סיו?
  4. Tammuz, 29 days תמו?
  5. Av, 30 days א?
  6. Elul, 29 days אלו?
  7. Tishri, 30 days תשר?
  8. Heshvan, 29/30 days חשו?
  9. Kislev, 29/30 days כסל?
  10. Tevet, 29 days טב?
  11. Shevat, 30 days שב?
  12. Adar 1, 30 days, intercalary month אדר ?
  13. Adar 2, 29 days אדר ?


Adar 1 is only added 7 times in 19 years. In ordinary years, Adar 2 is simply called Adar.

Hindu Calendar

The Hindu Calendar has various systems of naming the months. The months in the lunar calendar are:
  1. Chaitra
  2. Vaishaakha
  3. Jyaishtha
  4. Aashaadha
  5. Shraavana
  6. Bhaadrapada
  7. Aashvayuja
  8. Kaartika
  9. Maargashiirsha
  10. Pausha
  11. Maagha
  12. Phaalguna


These are also the names used in the Indian national calendar for the newly redefined months.

The names in the solar calendar are just the names of the zodiac sign in which the sun travels. They are
  1. Mesha
  2. Vrishabha
  3. Mithuna
  4. Kataka
  5. Simha
  6. Kanyaa
  7. Tulaa
  8. Vrishcika
  9. Dhanus
  10. Makara
  11. Kumbha
  12. Miina

Tamil calendar

  1. Chitirai
  2. Vaikasi
  3. Aani
  4. Aadi
  5. Aavani
  6. Purratasi
  7. Aiypasi
  8. Kaarthigai
  9. Maargazhi
  10. Thai
  11. Maasi
  12. Panguni

Iranian/Persian calendar

The Iranian / Persian calendar, currently used in Iran and Afghanistan, also has 12 months. The Persian names are included in the parentheses.
  1. Farvardin (فروردین)‎, 31 days
  2. Ordibehesht (اردیبهشت)‎, 31 days
  3. Khordad (خرداد)‎, 31 days
  4. Tir (تیر)‎, 31 days
  5. Mordad (مرداد)‎, 31 days
  6. Shahrivar (شهریور)‎, 31 days
  7. Mehr (مهر)‎, 30 days
  8. Aban (آبان)‎, 30 days
  9. Azar (آذر)‎, 30 days
  10. Dey (دی)‎, 30 days
  11. Bahman (بهمن)‎, 30 days
  12. Esfand (اسفند)‎, 29 days, 30 in leap years

Icelandic/Old Norse calendar

The old Icelandic calendar is not in official use anymore, but some holidays and annual feasts are still calculated according to it in Iceland. It has 12 months, broken down into two groups of six often termed "winter months" and "summer months". The calendar is peculiar in that the months always start on the same weekday rather than on the same date. Hence Şorri always starts on a Friday sometime between January 19 and January 25 (Old style: January 9 to January 15) , Góa always starts on a Sunday between February 18 and February 24 (Old style: February 8 to February 14).
  • Skammdegi ("Short days")
  1. Gormánuğur (mid October - mid November, "slaughter month" or "Gór's month")
  2. İlir (mid November - mid December, "Yule month")
  3. Mörsugur (mid December - mid January, "fat sucking month")
  4. Şorri (mid January - mid February, "frozen snow month")
  5. Góa (mid February - mid March, "Góa's month, see Nór")
  6. Einmánuğur (mid March - mid April, "lone" or "single month")
  • Náttleysi ("Nightless days")
  1. Harpa (mid April - mid May, Harpa is a female name, probably a forgotten goddess, first day of Harpa is celebrated as Sumardagurinn fyrsti - first day of summer)
  2. Skerpla (mid May - mid June, another forgotten goddess)
  3. Sólmánuğur (mid June - mid July, "sun month")
  4. Heyannir (mid July - mid August, "hay business month")
  5. Tvímánuğur (mid August - mid September, "two" or "second month")
  6. Haustmánuğur (mid September - mid October, "autumn month")

Notes

1. ^ Derived from ELP2000-85: M. Chapront-Touzé, J. Chapront (1991): Lunar tables and programs from 4000 B. C. to A. D. 8000. Willmann-Bell, Richmond VA; ISBN 0-943396-33-6
2. ^ Days in each month
3. ^ Happy New Year! Or is it? by Education World
4. ^ Mnemonics to improve memory
5. ^ The Boy Mechanic: A Handy Calendar (1913) from Project Gutenberg

See also

time.

One view is that time is part of the fundamental structure of the universe, a dimension in which events occur in sequence, and time itself is something that can be measured.
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calendar is a system for naming periods of time, typically days. These names are known as calendar dates. Cycles in a calendar are often synchronised with the perceived motion of astronomical objects.

A calendar is also a physical device (often paper).
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The orbital period is the time taken for a planet (or another object) to make one complete orbit.

When mentioned without further qualification in astronomy this refers to the sidereal period of an astronomical object, which is calculated with respect to the stars.
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Moon  

The Moon as seen by an observer on Earth
Orbital characteristics
Periapsis: 363,104 km
0.0024 AU
Apoapsis: 405,696 km
0.0027 AU
Semi-major axis: 384,399 km
0.
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Moon Phase can refer to:
  • Lunar phase, appearance of the illuminated portion of the Moon as seen by an observer
  • Tsukuyomi -Moon Phase-, a manga series by Keitarō Arima

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day (symbol: d) is a unit of time equivalent to 24 hours. It is not an SI unit but it is accepted for use with SI.[1] The SI unit of time is the second. The term comes from the Old English dæg.

Definitions

The day has several definitions.
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archaeological excavation has a double meaning.
  1. Excavation is the best-known and still the most commonly used technique within the science of archaeology. In this sense it is the ', processing and recording''' of archaeological remains.

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A tally (or tally stick) was an ancient memory aid device to record and document numbers, quantities, or even messages. While the origin of this technique is lost in prehistory, archaeological proof of the existence of such devices is ample.
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Paleolithic is a prehistoric era distinguished by the development of stone tools. It covers virtually all of humanity's time on Earth, extending from 2.5 million years ago, with the introduction of stone tools by hominids such as Homo habilis
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ORBit is a CORBA compliant Object Request Broker (ORB). The current version is called ORBit2 and is compliant with CORBA version 2.4. It is developed under the GPL license and is used as middleware for the GNOME project.
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Hebrew calendar (Hebrew: הלוח העברי‎) or Jewish calendar is the calendar used by Jews for religious purposes.
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Islamic calendar or Muslim calendar (Arabic: التقويم الهجري; at-taqwīm al-hijrī
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New Moon is the lunar phase that occurs when the Moon, in its monthly orbital motion around Earth, lies between Earth and the Sun, and is therefore in conjunction with the Sun as seen from Earth.
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Karaite Judaism or Karaism is a Jewish movement characterized by the sole reliance on the Tanakh as scripture, and the rejection of the Oral Law (the Mishnah and the Talmud) as halakha (Legally Binding, i.e., required religious practice).
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celestial sphere is an imaginary rotating sphere of "gigantic radius", concentric and coaxial with the Earth. All objects in the sky can be thought of as lying upon the sphere.
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STAR is an acronym for:

Organizations:
  • Society for Telescopy, Astronomy, and Radio, a non-profit astronomy club in New Jersey
  • Special Tasks and Rescue or Special Tactics and Response, synonyms for SWAT

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A nakshatra (Devanagari: नक्षत्र) or lunar mansion
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In astronomy, an asterism is a pattern of stars seen in Earth's sky which is not an official constellation. Like constellations, they are composed of stars which, while they are in the same general direction, are not physically related, often being at significantly
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equinox can have two meanings:
  • The moment when the Sun is positioned directly over the Earth's equator and, by extension, the apparent position of the Sun at that moment - see below.

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Precession refers to a change in the direction of the axis of a rotating object. In physics, there are two types of precession, torque-free and torque-induced, the latter being discussed here in more detail.
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ecliptic is the apparent path that the Sun traces out in the sky, as it appears to move in the sky in relation to the stars, this apparent path aligns with the planets throughout the course of the year.
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A tropical year (also known as a solar year) is the length of time the Sun, as seen from the Earth, takes to return to the same position along the ecliptic (its path among the stars on the celestial sphere) relative to the equinoxes and solstices.
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The Sun

Observation data
Mean distance
from Earth 1.4961011 m
(8.31 min at light speed)
Visual brightness (V) −26.74m [1]
Absolute magnitude 4.
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The orbit of the Moon around the Earth is completed in approximately 27.3 days. The Earth and Moon orbit about their common center of mass, which lies about 4,700 kilometres from Earth's center (about three quarters of the Earth's radius).
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Perigee is the point at which an object in orbit around the Earth makes its closest approach to the Earth. This term commonly refers to the Moon but can be applied to any earth-orbiting body, such as artificial satellites.
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nodal period is about twice as long as the apsidal precession period discussed above. After the nodal period, the number of draconic months counted exceed the number of sidereal months counted by exactly one: this happens after about 6793 days (18.6 years).
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ECLiPSe is a constraint logic programming system that implements a programming language close to Prolog. ECLiPSe was developed until 1995 at the European Computer‐Industry Research Centre (ECRC) in Munich and then until 2005 at the Centre for Planning and Resource Control at
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The Saros cycle is an eclipse cycle with a period of about 18 years 11 days 8 hours (approximately 6585⅓ days) that can be used to predict eclipses of the Sun and Moon.
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