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In Memoriam:

To the late O.L. Harvey
of Silver Spring, Maryland,
who loved Julian Day Numbers.

Julian Day Numbers for dates on the Gregorian and Julian Calendars
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On the gangway the master lowered his sextant, walked aft to Mr
Hervey and said, 'Twelve o'clock, sir: fifty-eight minutes [of
latitude] north.'

The first lieutenant turned to [Captain] Jack [Aubrey], took off
his hat and said, 'Twelve o'clock, sir, if you please, and
fifty-eight minutes north.'

Jack turned to the officer of the watch and said, 'Mr Nicholls,
make it twelve.'

The officer of the watch called out to the mate of the watch, 'Make
it twelve.'

The mate of the watch said to the quartermaster, 'Strike eight
bells'; the quartermaster roared at the Marine sentry, 'Turn the
glass and strike the bell!'

Patrick O'Brian, H.M.S. Surprise, W.W. Norton & Company, 1973,
p.118
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Julian Day Numbers, or the Julian Date (JD), is the absolute count of
days that have elapsed since Noon 1 January 4713 BC/BCE on the Julian
Calendar, or on what may more strictly be called the Julian
"Proleptic" Calendar, meaning the Julian Calendar as applied to an era
prior to its actual use. That use began with Julius Caesar in 46
BC/BCE. That the Julian Day begins at Noon reflects the practice of
the Astronomical or Nautical Day before 1925 -- which made the noon
sighting at sea of particular importance, as commemorated by Patrick
O'Brian above. The Civil Day of the same calendar date began the
Midnight before the Astronomical or Nautical Day.

The device of Julian Day Number was introduced by Joseph Scalinger
(1540-1609). It effectively ended the use of the Egyptian calendar and
the Era of Nabonassar for astronomical purposes, as had been
introduced by Claudius Ptolemy (c.100-c.170 AD). Scalinger picked 4713
BC because it was the first year on a number of different calendar
cycles and was earlier than any possible historical dates that he knew
of. "Julian Day Numbers" may refer to integer numbers corresponding to
whole days, while the "Julian Date" may mean an integer plus decimal
that brings the Julian count down to precise parts of a day.

To convert dates from the Julian or Gregorian calendars to Julian Day
Numbers, first the year of the Julian Period must be determined. An
AD/CE year is simply added to 4713. Thus, 1997 yields 6710. Years
BC/BCE must be expressed as negatives of AD/CE years. 747 BC
corresponds to -746 AD (since 1 BC = 0 AD) = 3967. But the year of the
Julian Period is awkward for purposes of calculation. If 4713 BC is
set to Year 0 instead of Year 1, this is more convenient. The
"Scalinger Year" is thus one less than the year of the Julian Period,
and may be obtained by adding 4712 instead of 4713 to the year of the
AD/CE era.

For the year 1997, the Scalinger Year is 6709. Also for purposes of
calculation, the calendar year is taken to begin on 1 March instead of
January 1. January and February 1997 are thus reckoned to be in 1996
(6708). The Scalinger Year is then divided by 4. 6709/4 = 1677 with a
remainder of 1. 1677 is the number of four years cycles in the Julian
Calendar and 1 is the year (0-3) in the current cycle.

1677 is then multipled by the number of days in four Julian years,
1461, and 1 is multiplied by the number of days in a common Julian
year, 365. 1677 x 1461 + 1 x 365 = 2,450,462

For the month,

The Months of the Julian and Gregorian Calendars
Month Day Month Day Month Day
3. March 0 7. July 122 11. November 245
4. April 31 8. August 153 12. December 275
5. May 61 9. September 184 1. January 306
6. June 92 10. October 214 2. February 337

a day number must be found on the following table. If we are in the
month of September, the corresponding day number is 184

With the day of the month, let's say 21, the number for the month
(184) is added to the previous sum: 2,450,462 + 184 + 21 = 2,450,667

Two things must be done to 2,450,667 before we are finished. First,
since we are using 1 March as the beginning of the year, the number of
days elapsed from 1 January 4713 to 0 March 4713 must added. That is
59.

Century Correction Century Correction
1582    -10        1800    -12
1600               1900    -13
1700    -11        2000

Second, if we are using the Gregorian Calendar, a correction must be
added to reduce the date on the Julian calendar to that on the
Gregorian. For the period of the use of the Gregorian calendar, the
corrections are listed in the following table. The corrections are
listed as negative numbers so that ALL numbers may be added to produce
the Julian Day Number.

Thus, the Julian Day Number for 21 September 1997 on the Gregorian
Calendar is 59 + 2,450,667 + -13 = 2,450,713. The Julian Date of the
corresponding Civil Day, beginning the previous midnight, may be
obtained by subtracting 0.5 from the Julian Day Number: 2,450,667 -
0.5 = 2,450,712.5

Julian Day Numbers or Julian Dates are commonly stated in "myriads,"
i.e. 10,000s, instead of thousands. Thus, JD 2,450,713 may be seen
expressed as JD 2450 713 or as JD 245 0713.

Converting a Julian Day Number to Julian or Gregorian dates proceeds
in reverse from the procedure above. For example, JD 2,450,766. First
59 is subtracted from this = 2,450,707.

Century Correction Century Correction
1582    -10        1800    -12
1600               1900    -13
1700    -11        2000

Then the entire number is to be divided by 1461. This yields a
Quotient of 1677 and a Remainder of 610. The Remainder is then to be
divided by 365, with the quotient and remainder noted, in this case 1
and 245. The Quotient (1677) is then multiplied by 4 and added to the
quotient (1) = 6709. This is the Scalinger Year, unless the month
turns out to be January or February. The AD/CE year may be obtained by
subtracting 4712 = 1997. If we wish a date on the Gregorian Calendar,
the Gregorian Correction should be Subtracted from the remainder of
the above procedure (245). The Gregorian correction for 1997 is -13:
245 - -13 = 245 + 13= 258.

The Months of the Julian and Gregorian Calendars
Month Day Month Day Month Day
3. March 0 7. July 122 11. November 245
4. April 31 8. August 153 12. December 275
5. May 61 9. September 184 1. January 306
6. June 92 10. October 214 2. February 337

The table of months is then searched to find a day number smaller than
the remainder of the procedure above (258). This proves to be 245, for
November.

Substracting 245 from 258 gives us the day of the month = 13. JD
2,450,766 is thus Noon 13 November 1997 on the Gregorian Calendar. If
we had found January or February in the month table, we would reckon
the date as in the following year (i.e. 1998)

Dates on the Julian Calendar are obtained simply by ignoring the
factor of the Gregorian Correction.
_________________________________________________________________

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Copyright (c) 1997, 1999, 2004 Kelley L. Ross, Ph.D. All Rights Reserved
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Islâmic Dates with Julian Day Numbers
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Year Day  Year Day  Year Day
00   0    10*  3543 20   7087
01   354  11   3898 21*  7441
02*  708  12   4252 22   7796
03   1063 13*  4606 23   8150
04   1417 14   4961 24*  8504
05*  1771 15   5315 25   8859
06   2126 16*  5669 26*  9213
07*  2480 17   5315 27   9568
08   2835 18*  6378 28   9922
09   3189 19   6733 29*  10276
30   10631
* = leap years

To convert an Islâmic or Annô Hegirae date to Julian Day Numbers, e.g.
12 Rajab 1418, first divide the year by 30, noting the Quotient and
the Remainder of the division. With 1418, this yields a Quoteint of 47
and a Remainder of 8. Multiply the Quotient by 10631, the number of
days in the Islâmic 30-year calendar cycle. This yields 499,657. With
the Remainder, which is the year within the cycle, search the
following table for the year number and note the corresponding number
of days. Thus, year 8 corresponds to 2835 days.

Add 2835 to the previous product: 499,657 + 2,835 = 502,492.

The Months of the Moslem Calendar
Month Day Month Day Month Day
1. alMuh.arram 0 5. Jumaadaa l'uulaa 118 9. Ramad.aan 236
2. S.afar 30 6. Jumaadaa l'aaxirah 148 10. Shawwaal 266
3. Rabii'u l'awwal 59 7. Rajab 177 11. Duu lQa'dah 295
4. Rabii'u ttaanii 89 8. Sha'baan 207 12. Duu lH.ijjah 325

Now, search this table for the month and note the corresponding day.
For Rajab, the day is 177.

Add the day number (177) for the month (Rajab) and the day of the
month (12) to the previous product: 502,492 + 177 + 12 = 502,681

The Julian Date or Julian Day Number is then that number plus the
Islâmic Benchmark number, which is 1948,085, which is the Julian Date
of 0 Muh.arram 0 AH. Thus 502,681 + 1948,085 = 2,450,766.

Since the Julian Day begins at Noon (the pre-1925 convention of the
Astronomical or Nautical Day), the Day Number for the corresponding
Civil Day may be obtained by substracting 0.5 = 2,450,765.5. This
corresponds to 00:00 13 November 1997 on the Gregorian calendar. The
Islâmic Calendar Day itself begins at the previous Sunset whose civil
time will depend on the time of year, the latitude, and the time zone.
This is not easily represented with fractional Day Numbers (averaging
N.25), so the integer day, 2,450,766, might be used to represent 12
Rajab 1418 in its entirety.

Converting the Julian Day Number to the Annô Hegirae date repeats the
above process in reverse. Given the Julian Date 2,450,713, substract
the Islâmic Benchmark number, 2,450,713 - 1948,085 = 502,628.

Year Day  Year Day  Year Day
00   0    10*  3543 20   7087
01   354  11   3898 21*  7441
02*  708  12   4252 22   7796
03   1063 13*  4606 23   8150
04   1417 14   4961 24*  8504
05*  1771 15   5315 25   8859
06   2126 16*  5669 26*  9213
07*  2480 17   5315 27   9568
08   2835 18*  6378 28   9922
09   3189 19   6733 29*  10276
30   10631
* = leap years

This number must be divided by 10631 with Quotient and Remainder
noted. The Quotient is 47 and the Remainder 2971. The year table is
then examined for a day number smaller than the Remainder, 2971.

In this case, day number 2835, with year 8, is smaller than 2971. The
Quotient of the previous division, 47, is then multiplied by 30 and
added to the year number (8), 47 x 30 = 1410, 1410 + 8 = 1418. This is
the Year of the Annô Hegirae era corresponding to our Julian Day
2,450,713.

The Months of the Moslem Calendar
Month Day Month Day Month Day
1. alMuh.arram 0 5. Jumaadaa l'uulaa 118 9. Ramad.aan 236
2. S.afar 30 6. Jumaadaa l'aaxirah 148 10. Shawwaal 266
3. Rabii'u l'awwal 59 7. Rajab 177 11. Duu lQa'dah 295
4. Rabii'u ttaanii 89 8. Sha'baan 207 12. Duu lH.ijjah 325

Then day number 2835 is subtracted from the Remainder of the previous
division (2971), yielding 136. The Month table is then examined for a
number smaller than 136. This turns out to be 118, the number
corresponding to the month Jumaadaa l'uulaa.

The month thus will be Jumaadaa l'uulaa, and the day of the month will
just be the month's day number (118) substracted from the previous
difference (136). This yields 18. The Annô Hegirae era date
corresponding to our Julian Day 2,450,713 is thus 18 Jumaadaa l'uulaa
1418.
_________________________________________________________________

Philosophy of Science

Philosophy of Religion

Philosophy of History

Home Page

Copyright (c) 1997, 1999 Kelley L. Ross, Ph.D. All Rights Reserved
_________________________________________________________________

Julian Day Numbers, Note
_________________________________________________________________

American usage, where the comma separates thousands and the period is
used to indicate decimals, is observed.

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