Solve Pi: What if Its Remainder is 0?

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In summary, the conversation discusses the possibility of pi being a rational number and the implications this would have for mathematics and practical sciences. It is proven that pi is irrational, so this scenario is unlikely. The conversation also touches on the importance of calculating pi to many decimal places and the possibility of a different number system where pi may have a different value.
  • #1
Chaos' lil bro Order
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I was wondering what would happen if someone found out that Pi had a remainder of 0 down the line, some billion or trillion or whatever decimels away.

What implications would this have for practical sciences?

All thoughts appreciated, ty.
 
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  • #2
You're asking: what would happen if we eventually discovered that pi was a rational number?

It would break a very large amount of the mathematical machinery that we have created to date.

- Warren
 
  • #3
Pi is proven to be irrational, so no danger there.
 
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  • #4
It would be a proof by contradiction of something, most likely that the algorithm used to compute the digits is wrong.
 
  • #5
If the universe were perfectly euclidean (all straight lines are really straight, defined in terms of parallel lines) then your question would be nonsense, but since we know that the geometry of spacetime trajectories is non-euclidean, and not perfectly understood/classified, I can for the sake of discussion consider that we inhabit a universe where every perfect measurement of a circles radius and circumfrence would have these commeasurate (that is, in a rational ratio).

This would have less of an effect on macroscopic physics then quantum mechanics, and QM already has very little effect.
 
  • #6
Thank you for the expert replies.

Who proved Pi to be irrational and could a math novice such as I understand such a proof?

Also, why do mathematician's bother to further refine Pi's value to millions of decimel places, are there formulas that scientists use that make more accurate predictions based on futher refinements on Pi? Perhaps, we can more accurately send a shuttle into orbit or something like this, or is this off base.
 
  • #7
Chaos' lil bro Order said:
Also, why do mathematician's bother to further refine Pi's value to millions of decimel places, are there formulas that scientists use that make more accurate predictions based on futher refinements on Pi?
One interesting thing you get from it is to see up to what extent [itex]\pi[/itex] is random (it is assumed to be random but not proven).

See for instance http://www.mathpages.com/home/kmath519.htm" [Broken] about this but then for e.
 
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  • #8
No, there is no particular use for calculating [itex]\pi[/itex] to many decimal places, at least with regard to any practical problem. My computer can calculate [itex]\pi[/itex] to 100,000 digits in a second, and that is with 77 Firefox windows, two Maple windows, music playing, and a number of other programs running (for some reason I've never liked tabs much :wink:)! If I required it, I could have 10,000,000 digits in half an hour. Even at the 1,000 digit level there would be no practical calculation that wouldn't include other sources of uncertainty much, much larger.

I'm sure there are many proofs of pi's irrationality online. Just google "proof that pi is irrational," or some such.
 
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  • #9
http://www.mathpages.com/home/kmath313.htm
Here's a proof, and in the first sentence it says who proved it first. You can follow it if you know calculus. There's not really anything to understand though. It seems they arrived at a useful inequality more or less by luck.
 
  • #10
Crosson said:
If the universe were perfectly euclidean (all straight lines are really straight, defined in terms of parallel lines) then your question would be nonsense, but since we know that the geometry of spacetime trajectories is non-euclidean, and not perfectly understood/classified, I can for the sake of discussion consider that we inhabit a universe where every perfect measurement of a circles radius and circumfrence would have these commeasurate (that is, in a rational ratio).

This would have less of an effect on macroscopic physics then quantum mechanics, and QM already has very little effect.
That's not true. [itex]\pi[/itex] is a specific number that is definitely irrational. What you should say is that the could exist a portion of space in which the ratio of circumference to diamer of a circle is a rational number rather than [itex]\pi[/itex]- but that has no effect on the number [itex]\pi[/itex].
 
  • #11
HallsofIvy said:
That's not true. [itex]\pi[/itex] is a specific number that is definitely irrational. What you should say is that the could exist a portion of space in which the ratio of circumference to diamer of a circle is a rational number rather than [itex]\pi[/itex]- but that has no effect on the number [itex]\pi[/itex].

I don't know much about this. But even if we were in a different space where the ratio was rational, we probably have to use Pi itself to even solve the ratio in the first place. :uhh:
 
  • #12
No, I see no reason for that. Certainly we can imagine a world where ratio of circumference to diameter of some circles is 3. No need to introduce pi at all.

(I said some circles because while in Euclidean geometry that ratio is the same for all circles, pi, in any non-Euclidean geometry, it varies with the size of the circle.)
 
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  • #13
Simplest Definition for Pi - Ratio of the Circumference to the Diameter of a Circle IN EUCLIDEAN SPACE.

If we were in a different space where the ratio of rational, we would make bigger problems for ourselves by using pi because since pi is irrational, the constant by which you multiply pi to get this rational value must also be irrational and an expression involving pi. I seemed to be quite confusing there...
 
  • #14
I agree with you all, archimede's constant [tex] \pi [/tex] is a well defined irrational number, sorry for the confusion.

Because of the following remark:
What implications would this have for practical sciences?
I thought that OP was interested in the usual physical interpretation of [tex] \pi [/tex] --- as the empirical ratio of circumfrence to diameter in our reality.

I realize this is the math forum, but the math interpretation of the OP's question is so nonsensical I treated it as a misplaced physics question.
 
  • #15
What if pi was based in a different system. There could be a different base or altogether different way to add up numbers. Think of a quadratic number system instead of base10, base2, etc...
 
  • #16
bassplayer142 said:
What if pi was based in a different system. There could be a different base or altogether different way to add up numbers. Think of a quadratic number system instead of base10, base2, etc...
What do you mean by a "quadratic number system"? And exactly what are you asking?
 
  • #17
In any other integer base than 10, pi is still irrational.
 
  • #18
n/m. scratch that.
 
  • #19
Since Pi is irrational, would it be logical to think that the string of digits go through every possible number of combinations? If that were true somewhere down the line of digits is this very post is encoded in binary; It may take massive amounts of calculations and perhaps more time than the age of the universe, but you would find it starting at the nth decimal place at some inconcievably large number.

Just a thought, nothing more.
 
  • #20
Universe_Man said:
Since Pi is irrational, would it be logical to think that the string of digits go through every possible number of combinations?

If pi is normal, then yes, otherwise that's not at all guaranteed. 1.01001000100001... is irrational, but the number combination "2" never appears at all (this is a decimal representation!).

All evidence suggests that pi is normal, though no one's been able to prove it yet...
 
  • #21
If pi wasn't completely random then wouldn't you also be able to representing it in some integral base number system?
 
  • #22
turbobum said:
If pi wasn't completely random then wouldn't you also be able to representing it in some integral base number system?

If you mean representing it as a finite digit string in some integral base number system, no. Being rational or irrational has nothing to do with the number system nor does the fact that only rational numbers (and not all of them) can be represented by a finite digit string. (Precisely which rational number can be so represented does depend on the base. Only those rational number which, represented as a fraction reduced to lowest terms, have denominator all of whose prime factors are also factors of the base can be represented as a finite "decimal".)
 

1. What is Pi and why is it important?

Pi is a mathematical constant that represents the ratio of a circle's circumference to its diameter. It is an irrational number, meaning it cannot be expressed as a finite decimal or fraction. Pi is important because it is used in many mathematical equations and has numerous applications in fields such as geometry, physics, and engineering.

2. How do we calculate Pi?

Pi can be calculated using various methods, such as infinite series or geometric constructions. One common method is the Leibniz formula, which states that Pi equals 4 times the sum of the alternating series 1 - 1/3 + 1/5 - 1/7 + 1/9 - ...

3. What is the significance of a remainder of 0 when solving for Pi?

A remainder of 0 when solving for Pi means that the calculated value is an exact multiple of Pi. This can be useful in certain mathematical equations and can also help verify the accuracy of the calculation method used.

4. Can Pi ever be fully solved?

No, Pi is an irrational number, meaning it has an infinite number of digits and cannot be fully solved. However, with the help of computers, we can calculate Pi to trillions of digits, but it will never be fully solved.

5. What are the practical applications of knowing the value of Pi?

The value of Pi is used in various fields, such as engineering, architecture, and physics, to accurately calculate measurements and solve equations. It is also used in technology, such as GPS systems, to accurately determine locations and distances.

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