# If I wanted to work using dates and time going millions of years into the past/future how would I do it?

If I wanted to work using dates and time going millions of years into the past/future how would I do it in C/C++/C#?

For example say I was working on an algorithm to see if a comet was going to hit the earth? Are there commercial or open source libraries that do this?

Most DateTime values only work for a few years. Unixes will run out in only 2038!.

Tony

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Sounds like homework to me –  S.Lott Dec 15 '08 at 17:58
Is the complete date and time important on such large scales? "I calculated, that on 2/29/74899992 9:11 a.m. a comet will hit the earth?" ;-) –  splattne Dec 15 '08 at 18:00
Most unices do have 64 bit time_t now, which puts their end time way ahead of what you'll ever need. –  mat Dec 15 '08 at 18:10
Another thought: With those long time spans, the Uncertainty Principle might have an effect, even with very big masses. –  Treb Dec 16 '08 at 11:17

Astronomers use their own calendar, different from the civil, Gregorian calendar.

Astronomical Julian Dates are what they use.

Here's a typical package: Solar Clock.

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You can't work out future UTC dates down to the second, because of the existence of leap seconds (one of which is scheduled for December 31, a couple of weeks from now). No one knows when leap seconds will be added to the calendar, because no one knows the rate at which the Earth's rotation will continue to slow in the future.

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Good point! +1 ;-) –  Treb Dec 15 '08 at 18:12
I think if you're trying to predict when a meteor will crash into the earth, possibly obliterating all human life, I don't think needing to know exactly what second is imperative :P –  BenAlabaster Dec 15 '08 at 18:17
but you only need 86,400 missed leap seconds to miss a whole day. if you go millions of years away, it's a 'built-in' uncertainty of around 1:3e7 (assuming 0-2 leap seconds a year) –  Javier Dec 15 '08 at 18:42
@Javier: it isn't 0-2 leap seconds per year. It's much less than that. It's less than 0-2 per decade overall. But it is random. –  S.Lott Jan 9 '09 at 20:59

Well, not to be blunt or anything, but if it will hit the earth in like 1700 years, I don't think we'll need to know the actual date.

Unless it's a tuesday.

Never could get the hang of tuesdays.

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When Kang and Kodos take over, they'll impose a new calendar anyway. –  S.Lott Dec 15 '08 at 18:06
It can't be a Tuesday, I have meetings... can we reschedule? :P –  BenAlabaster Dec 15 '08 at 18:18
The Douglas Adams quote is actually Thursday. –  Echostorm Dec 15 '08 at 18:31
Let him worry about thursdays, my problem is tuesdays! –  Lasse V. Karlsen Dec 15 '08 at 18:40

If the time span offered by typical datetime variables is too small, you have two options:

1. Using a variable with a bigger scope (i.e. more bits)
2. Allowing for less precision

Which one you should choose depends on what exactly you want to do. But in general, my advice is option number 2. When we are talking about centuries or millenia, milliseconds are usually not that important...

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When it comes to astronomical events, it doesn't matter which part of the earth is facing the Sun, i.e. has daylight. Therefore, calendars and dates are irrelevant too. You should simply use time. A 64 bit time_t for instance is quite sufficient.

Even when you do use time, keep in mind that 3-body systems (like Earth-Sun-Jupiter) are chaotic. Predicting the position of the Earth in the far future has a rather large margin of error.

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lets predict it stays Sun, Earth, Jupiter for some time to come - shall we! –  AnthonyLambert Dec 16 '08 at 12:52

A 64-bit time_t will work until the year 292,277,026,596.

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You just need more bits to store the value and/or use larger increments of time to represent by the timestamp. Instead of ms, do years, then possibly use a math library/API designed for very large numbers if that isn't enough (and depending on your precision requirements) or use floating point.

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