Difference between revisions of "Helios calendar"

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Time on [[Earth]] has little meaning to someone who spends their life on another planet. While [[Martian]] calendars and clocks have existed since the 20th century, coordinating calendars for every last rock is untenable.  In addition, compared to an observer outside of any gravitational well, a second on [[Earth]] is, in actuality, only 0.9999999889263968688 of a second.
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Time on [[Earth]] has little meaning to someone who spends their life on another planet. While [[Martian calendar]]s and clocks have existed since the 20th century, coordinating calendars for every last rock is untenable.  As the years progress, precession, tidal dragging, and other factors adjust the time it takes for a body to rotate and orbit - already responsible for a day of error since Egyptian times.  Even relativity causes problems.  Compared to a stationary observer outside of the [[solar]] gravitational well, a second on [[Earth]] is, in actuality, only about 0.999999984345 of a second.
  
The following was devised as a solution, at least in the context of the [[Solar System]]. As [[human]]ity takes the stars, the [[Silver Calendar]] will be refined and implemented, though the [[Helios Calendar]] is still fairly accurate on these scales.
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The [[Helios calendar]] was devised as a solution, at least in the context of the [[Solar System]], and is sometimes referred to as 'the Solar calendar' (note capitalization). When corrected properly for the nearest major, singular masses, it is fairly accurate, even outside the solar system.
  
See the [[Martian Calendar]] for timekeeping on [[Mars]].
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See the [[Arean calendar]] for timekeeping on [[Mars]], and [[Gregorian calendar]] for the (slightly) modified [[Earth]] calendar.
 
 
The [[Helios Calendar]] is also sometimes referred to as 'the' '''Solar Calendar'''.  This use is somewhat frowned upon since it has little in common with the standard idea of a solar calendar.
 
  
 
== Mechanics ==
 
== Mechanics ==
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At its core, the [[Helios calendar]] has a lot in common with the Julian Date, though the intent is to have a reference completely independent of [[Earth]].  Specifically, it measures the number of true [[hour]]s since the beginning of the epoch (as in, groups of 3,600 [[second]]s or 216,000 [[third]]s).  Officially, it is also grouped into 'solar [[month]]s' of a thousand hours and 'solar [[cycle]]s' of a thousand months.  People often add an additional unit, with a 'solar day' being 25 hours long and having 40 days to the month.
  
The [[Helios Calendar]] is fairly simple, with only one unit. It defines the [[Solar Month]] as being one full rotation of the [[Sun]] at its equator. This is about 25 days, 9 hours, 7 minutes and 12 seconds. The exact value (2,192,832 seconds) is used rather than taking the minor variations in the [[Sun]]'s rotation into account, of course. Time is tracked on the sole basis of this specific measure of the sun's rotation and thus, the [[Helios Calendar]] does not proceed at exactly the same rate [[Terran]] time does.
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The epoch of the [[Helios Calendar]] begins with the legendary [http://sunearth.gsfc.nasa.gov/eclipse/SEcat/SE-0799--0700.html June 15th, 763 B.C.E] solar eclipse during its maximum at 08:23 UT ('GMT') on the Julian Calendar ([[Julian Date]] 1,442,902). According to Roman legend, Remus was conceived during this eclipse, and it is mentioned in an Assyrian tablet known as the Eponym Canon. It is perhaps the most familiar as the eclipse referred to in Amos 8: "And it shall come to pass in that day, saith the Lord GOD, that I will cause the sun to go down at noon, and I will darken the earth in the clear day." (KJV)
  
The epoch of the [[Helios Calendar]] begins with the legendary June 15th, 763 B.C.E solar eclipse during its maximum at 08:23 GMT. According to Roman legend, Remus was conceived during this eclipse, and it is mentioned in an Assyrian tablet known as the Eponym Canon. It is perhaps the most familiar as the eclipse referred to in Amos 8: "And it shall come to pass in that day, saith the Lord GOD, that I will cause the sun to go down at noon, and I will darken the earth in the clear day." (KJV)
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* [http://ss.anenris.com/resources/calendar.html Solar Storms Calendar Converter]
  
== Example Gregorian - Helios dates ==
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== Common Usage ==
The 42,633rd [[Solar Month]] occurs about 20 days before 2201's New Year on [[Earth]]. Or simply, it's called the 633rd for short.
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A date is typically written as 24.277.522:17:17 (Midnight, January 1st, 2008, UTC), when fully written out.  Terms like '[[cycle]] 24', or 'the 24th cycle', are common, as are phrases like '[[month]] two-seventy-seven' when the cycle is obviously known, or 'hour five-twenty-two' when the month is.
 
 
January 1st, Midnight GMT, 2201 is 42,633 Solar Months, 22 days, 5 hours, 12 minutes, and ~16 seconds after the begining of the epoch. The additional ~9,172 seconds (if you bothered with the math) is due to relativity - [[Earth]] experiences time about a hundredth of a millionth slower than an object in 'static' space meaningfully outside any gravitational well.
 
 
 
February 22nd, Midnight GMT, 2222 is 42,938 Solar Months, 3 days, 7 hours, 37 minutes, and ~21 seconds after the beginning of the epoch.
 
  
The 40,000th month began on December 23rd, 2017 at 5:59:34 AM GMT50,000 will begin on November 10th, 2712 at 5:23:43 AM GMT.
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Since the basic subunit is the hour, outside of [[Earth]], [[Luna]], and [[Mars]], a day is frequently considered to be 25 hours long, with 40 days to the month.  A week is usually considered to be ten days long, referred to as quarters - "first week/quarter, second week/quarter", etc.
  
[http://ss.anenris.com/resources/calendar.html Helios Calendar - Gregorian Calendar converter]
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While it was not, originally, intended as a social calendar, it has quickly gained acceptance as such, even on [[Earth]], due to communication between planets through [[satmet]]s requiring a more universal timescheme.
 
 
== Common Usage ==
 
The last three integral digits (938 in the 42,938th month, for example), are often used in much the same way the last two digits of a year are on [[Earth]].
 
  
'Dot' is often considered in much the same way an hour is.  At 42,133.416, the specific time of the month would be called 'Dot four-sixteen'Individually, a dot is .001 of a month, or about 36 and a half minutes.  Forty dots is roughly equivelant to a day on [[Earth]] or a [[sol]] on [[Mars]], and outside of those two contexts, but within that of standardized time, that is the assumed meaning of 'day'.
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After the [[Purge]], it has slowly become the dominant galactic calendarWhen corrected for local masses, it is exceedingly accurate within the nominal band drawn by [[Sol]] as it orbits the [[Milky Way]].  Moving closer to or further from the galactic center, or off the galactic plane, results in another slight difference usually termed [[drift]].  The same drift is also found when moving to another [[Galaxy]].  Even still, it remains a fairly standard measurement of time, with [[tachyon]]ic measurements used to measure the 'true' rate of time for a specific region (at least, with respect to another region).
  
 
{{SSG}}
 
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Latest revision as of 09:00, 17 April 2007

Time on Earth has little meaning to someone who spends their life on another planet. While Martian calendars and clocks have existed since the 20th century, coordinating calendars for every last rock is untenable. As the years progress, precession, tidal dragging, and other factors adjust the time it takes for a body to rotate and orbit - already responsible for a day of error since Egyptian times. Even relativity causes problems. Compared to a stationary observer outside of the solar gravitational well, a second on Earth is, in actuality, only about 0.999999984345 of a second.

The Helios calendar was devised as a solution, at least in the context of the Solar System, and is sometimes referred to as 'the Solar calendar' (note capitalization). When corrected properly for the nearest major, singular masses, it is fairly accurate, even outside the solar system.

See the Arean calendar for timekeeping on Mars, and Gregorian calendar for the (slightly) modified Earth calendar.

Mechanics

At its core, the Helios calendar has a lot in common with the Julian Date, though the intent is to have a reference completely independent of Earth. Specifically, it measures the number of true hours since the beginning of the epoch (as in, groups of 3,600 seconds or 216,000 thirds). Officially, it is also grouped into 'solar months' of a thousand hours and 'solar cycles' of a thousand months. People often add an additional unit, with a 'solar day' being 25 hours long and having 40 days to the month.

The epoch of the Helios Calendar begins with the legendary June 15th, 763 B.C.E solar eclipse during its maximum at 08:23 UT ('GMT') on the Julian Calendar (Julian Date 1,442,902). According to Roman legend, Remus was conceived during this eclipse, and it is mentioned in an Assyrian tablet known as the Eponym Canon. It is perhaps the most familiar as the eclipse referred to in Amos 8: "And it shall come to pass in that day, saith the Lord GOD, that I will cause the sun to go down at noon, and I will darken the earth in the clear day." (KJV)

Common Usage

A date is typically written as 24.277.522:17:17 (Midnight, January 1st, 2008, UTC), when fully written out. Terms like 'cycle 24', or 'the 24th cycle', are common, as are phrases like 'month two-seventy-seven' when the cycle is obviously known, or 'hour five-twenty-two' when the month is.

Since the basic subunit is the hour, outside of Earth, Luna, and Mars, a day is frequently considered to be 25 hours long, with 40 days to the month. A week is usually considered to be ten days long, referred to as quarters - "first week/quarter, second week/quarter", etc.

While it was not, originally, intended as a social calendar, it has quickly gained acceptance as such, even on Earth, due to communication between planets through satmets requiring a more universal timescheme.

After the Purge, it has slowly become the dominant galactic calendar. When corrected for local masses, it is exceedingly accurate within the nominal band drawn by Sol as it orbits the Milky Way. Moving closer to or further from the galactic center, or off the galactic plane, results in another slight difference usually termed drift. The same drift is also found when moving to another Galaxy. Even still, it remains a fairly standard measurement of time, with tachyonic measurements used to measure the 'true' rate of time for a specific region (at least, with respect to another region).


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