pi
-
it's not infinite, it's 3.14159265.... infinite is much bigger than that! ;P do you mean never repeat? 1st I believe you could have never repeating rationale (integer / integer) as well, this is simply an artefact of decimal notation. 2nd: yes PI is very special, it's a not even a real such as SQRT(2). Real number (as opposed to rational and integer) are solutino to polynomes equation (e.g. x^2 = 2) No Polynome with real parammters has PI has its solution. (same for 'e' (i.e. 2.7182818...)) they solve an other class of problem altogether...
Super Lloyd wrote:
PI is very special, it's a not even a real such as SQRT(2).
What do you mean? :wtf: Of course PI is a real number! The definition of a real number is that it's square should be nonnegative. And PI * PI is nonnegative. Cheers, Vikram.
I don't know and you don't either. Militant Agnostic
-
Super Lloyd wrote:
PI is very special, it's a not even a real such as SQRT(2).
What do you mean? :wtf: Of course PI is a real number! The definition of a real number is that it's square should be nonnegative. And PI * PI is nonnegative. Cheers, Vikram.
I don't know and you don't either. Militant Agnostic
As Chris Munder said, it's a Transcendental number[^], much more uncommon than mere real number.
-
It still didn't address the why. If it did, I didn't understand it. :) Jeremy Falcon
Gosh you got me. I remember doing this in school and I remember using it with integrals and the special number e. Your question doesn't seem to have a conclusive answer from mathematics other than, "Most mathematicians agree that PI is infinite, irrational and transcendental and would be very surprised to learn it wasn't." I remember one form of something we did was that prove pi isn't infinite. So we tried picking a ratio of integers to prove that but the ratio went on forever and a proof was used to demonstrate that. I don't remember the specifics but anyway... Get yourself a couple hundred crays and work it out. I guess they have PI to trillions of non repeating decimals so you'd need a few crays for sure...:omg:
A Plain English signature. Code-frog System Architects, Inc.
-
Sean Cundiff wrote:
All irrational numbers have the property that they are infinitely long, otherwise it would be possible to write them as P/Q and thus be a rational number.
Ok that makes sense. Given what you and Chris said, I suppose the idea I'm trying to understand then is why is Pi an irrational number? What makes it go on forever? And yeah, I'm trying to improve my math skills, so bear with me. :-O Jeremy Falcon
Jeremy Falcon wrote:
What makes it go on forever?
It's a number that is computed by an infinite series of smaller and smaller parts. For example, look at this.[^] Besides a lot of complicated equations, there's this very simple one: pi/4 = 1 - 1/3 + 1/5 - 1/7 ... You can see how the series is infinite, but smaller and smaller. So that's what makes it go on forever, and the resulting number is irrational, as discussed in the previous posts. Marc Pensieve Functional Entanglement vs. Code Entanglement Static Classes Make For Rigid Architectures
-
It still didn't address the why. If it did, I didn't understand it. :) Jeremy Falcon
Change the question around. Instead of asking "why can't Pi be expressed as P/Q", ask yourself "Why should any random real number (ie not an integer, not a complex number) be lucky enough to be expressable as P/Q" To have a number be able to be expressed, exactly, as a ratio of two other numbers is pretty remarkable. cheers, Chris Maunder
CodeProject.com : C++ MVP
-
Super Lloyd wrote:
do you mean never repeat?
I was under the impression it was infinite, just as 1/3 would also be. Jeremy Falcon
Ha.. but in that case it could be expressed as simple rational such as: big number divided by big power of ten. And why that couldn't be I hear you ask? 1st it would be funny that 10 would be a relevant number for a circle but why not.... Anyway, while I do not know the reason for that myself I could argue that this guy Ferdinand von Lindeman[^] proved PI was transcendental (no solution of any polynome with ration parameter), hence it obviously never repeat
-
Jeremy Falcon wrote:
What makes it go on forever?
It's a number that is computed by an infinite series of smaller and smaller parts. For example, look at this.[^] Besides a lot of complicated equations, there's this very simple one: pi/4 = 1 - 1/3 + 1/5 - 1/7 ... You can see how the series is infinite, but smaller and smaller. So that's what makes it go on forever, and the resulting number is irrational, as discussed in the previous posts. Marc Pensieve Functional Entanglement vs. Code Entanglement Static Classes Make For Rigid Architectures
Marc Clifton wrote:
So that's what makes it go on forever
Actually not quite. Infinite series can easily add up to a rational number, or even an integer. 1/2 + 1/4 + 1/8 + ... = 1 cheers, Chris Maunder
CodeProject.com : C++ MVP
-- modified at 22:38 Thursday 16th March, 2006
-
Super Lloyd wrote:
PI is very special, it's a not even a real such as SQRT(2).
What do you mean? :wtf: Of course PI is a real number! The definition of a real number is that it's square should be nonnegative. And PI * PI is nonnegative. Cheers, Vikram.
I don't know and you don't either. Militant Agnostic
Any number squared would be non-negative...:~
A Plain English signature. Code-frog System Architects, Inc.
-
Marc Clifton wrote:
So that's what makes it go on forever
Actually not quite. Infinite series can easily add up to a rational number, or even an integer. 1/2 + 1/4 + 1/8 + ... = 1 cheers, Chris Maunder
CodeProject.com : C++ MVP
-- modified at 22:38 Thursday 16th March, 2006
Chris Maunder wrote:
Infinite series can easily add up to a rational number, or even an integer.
Ah, good point. I better stick to programming. :) Marc Pensieve Functional Entanglement vs. Code Entanglement Static Classes Make For Rigid Architectures
-
Jeremy Falcon wrote:
What makes it go on forever?
It's a number that is computed by an infinite series of smaller and smaller parts. For example, look at this.[^] Besides a lot of complicated equations, there's this very simple one: pi/4 = 1 - 1/3 + 1/5 - 1/7 ... You can see how the series is infinite, but smaller and smaller. So that's what makes it go on forever, and the resulting number is irrational, as discussed in the previous posts. Marc Pensieve Functional Entanglement vs. Code Entanglement Static Classes Make For Rigid Architectures
Marc Clifton wrote:
You can see how the series is infinite, but smaller and smaller.
I got all of that stuff. But it doesn't explain why the series exist in the first place. Fortunately, I think I got enough info from the fine folks at CP to help me set out a course to improve my understanding on it. I'm just not there yet. :) Jeremy Falcon
-
Ha.. but in that case it could be expressed as simple rational such as: big number divided by big power of ten. And why that couldn't be I hear you ask? 1st it would be funny that 10 would be a relevant number for a circle but why not.... Anyway, while I do not know the reason for that myself I could argue that this guy Ferdinand von Lindeman[^] proved PI was transcendental (no solution of any polynome with ration parameter), hence it obviously never repeat
I'm getting the impression I need to hit the books again. :-D Jeremy Falcon
-
I'm trying to find a good way to explain why pi is infinite (not what it is). And I'm drawing up blanks. Any math gurus care to shed me some light please? Jeremy Falcon
-
Any number squared would be non-negative...:~
A Plain English signature. Code-frog System Architects, Inc.
Only 'real' numbers. There is a whole branch of mathematics that deals with SQRT(-1) these are called 'imaginary' numbers.
-
I haven't had anywhere near enough to drink. Can we start with something a little easier, like "what is the length of a piece of string"? :-O
Now taking suggestions for the next release of CPhog...
:) Simple, that would be 4. Next please. Jeremy Falcon
-
Any number squared would be non-negative...:~
A Plain English signature. Code-frog System Architects, Inc.
Those imaginary numbers (not real) are the i you see sometimes. It's sqrt(-1). Sometimes you can see numbers writen as
a + b_**i**_, which have a real and an imaginary part. You can read more about them here[^] -- LuisR
Luis Alonso Ramos Intelectix - Chihuahua, Mexico Not much here: My CP Blog!
The amount of sleep the average person needs is five more minutes. -- Vikram A Punathambekar, Aug. 11, 2005
-
Any number squared would be non-negative...:~
A Plain English signature. Code-frog System Architects, Inc.
code-frog wrote:
Any number squared would be non-negative
Not imaginary numbers, like i. By definition, i * i = -1. Cheers, Vikram.
I don't know and you don't either. Militant Agnostic
-
As Chris Munder said, it's a Transcendental number[^], much more uncommon than mere real number.
Super Lloyd wrote:
As Chris Munder said, it's a Transcendental number[^], much more uncommon than mere real number.
Erm, I never disagreed with that. You said PI is not real, and I only said it is. Cheers, Vikram.
I don't know and you don't either. Militant Agnostic
-
It still didn't address the why. If it did, I didn't understand it. :) Jeremy Falcon
Jeremy Falcon wrote:
It still didn't address the why.
It simply is. Go in peace. Be. Cheers, Vikram.
I don't know and you don't either. Militant Agnostic
-
code-frog wrote:
Any number squared would be non-negative
Not imaginary numbers, like i. By definition, i * i = -1. Cheers, Vikram.
I don't know and you don't either. Militant Agnostic
Vikram A Punathambekar wrote:
By definition, i * i = -1
Thankyou! Someone who gets the definition correct! :-D I see most people say that i = sqrt(-1), which is NOT correct - it implies that i2 = 1
Ryan
"Punctuality is only a virtue for those who aren't smart enough to think of good excuses for being late" John Nichol "Point Of Impact"
-
I'm trying to find a good way to explain why pi is infinite (not what it is). And I'm drawing up blanks. Any math gurus care to shed me some light please? Jeremy Falcon
Jeremy Falcon wrote:
I'm trying to find a good way to explain why pi is infinite (not what it is).
Because. :)
Ryan
"Punctuality is only a virtue for those who aren't smart enough to think of good excuses for being late" John Nichol "Point Of Impact"