Crosswords0 min ago
Does anyone have a comment on Euler's proof that God exists.
19 Answers
The mathematician Leonhard Euler believed the best empirical evidence for the existence of God is the following equation (which is easily derivable for anyone who remembers Taylor expansions):
e^(pi*i) + 1 = 0
e = The base of the natural logarithm
pi = The ratio of circumference of a circle to its diameter
i = The imaginary number, sqrt(-1)
1 = The multiplicative identity (x*1 = x)
0 = The additive identity (x+0 = x)
e^(pi*i) + 1 = 0
e = The base of the natural logarithm
pi = The ratio of circumference of a circle to its diameter
i = The imaginary number, sqrt(-1)
1 = The multiplicative identity (x*1 = x)
0 = The additive identity (x+0 = x)
Answers
In the hands of a statistician it could prove anything :-)
16:48 Fri 28th Sep 2012
I am unable to make head nor tale of the maths, but as far as I know, the idea that Euler advanced such a proof is just a story.
The link below also claims an entirely different equation, which I strongly suspect is no more or less sensible than the one in the original post. If it is a genuine equation, I would be interested to hear what it is supposed to demonstrate.
https://cs.uwaterloo.ca/~shallit/euler.html
The link below also claims an entirely different equation, which I strongly suspect is no more or less sensible than the one in the original post. If it is a genuine equation, I would be interested to hear what it is supposed to demonstrate.
https://cs.uwaterloo.ca/~shallit/euler.html
Another telling of the anecdote: https:/ /docs.g oogle.c ...~fra nz/M300 /bell3. pdf
It's an amazing mathematical formulae though which brings together so many of the key values used in maths :
e = The base of the natural logarithm
pi = The ratio of circumference of a circle to its diameter
i = The imaginary number, sqrt(-1)
In my maths studies I missed the perceived religious significance of it.
e = The base of the natural logarithm
pi = The ratio of circumference of a circle to its diameter
i = The imaginary number, sqrt(-1)
In my maths studies I missed the perceived religious significance of it.
Some numbers are intrinsically more important than others. Prime numbers are a well known example.
There are even more special numbers such as the Heegner Numbers:
1, 2, 3, 7, 11, 19, 43, 67, 163
http://en.wikipedia.org/wiki/Heegner_number
Expressions based on these numbers lead to outcomes that are not intuitively expected even though most of them have been fully explained with a mathematical justification.
Almost integer expressions are quite interesting.
http://en.wikipedia.org/wiki/Almost_integer
My favourite almost integer is e^(pi* sqrt(163)).
There are even more special numbers such as the Heegner Numbers:
1, 2, 3, 7, 11, 19, 43, 67, 163
http://en.wikipedia.org/wiki/Heegner_number
Expressions based on these numbers lead to outcomes that are not intuitively expected even though most of them have been fully explained with a mathematical justification.
Almost integer expressions are quite interesting.
http://en.wikipedia.org/wiki/Almost_integer
My favourite almost integer is e^(pi* sqrt(163)).
Just to save you reading the page here is the important part:
"Briefly, is an integer for d a Heegner number, and via the q-expansion.
If is a quadratic irrational, then the j-invariant is an algebraic integer of degree , the class number of and the minimal (monic integral) polynomial it satisfies is called the Hilbert class polynomial. Thus if the imaginary quadratic extension has class number 1 (so d is a Heegner number), the j-invariant is an integer.
The q-expansion of j, with its Fourier series expansion written as a Laurent series."
See. Simple!
"Briefly, is an integer for d a Heegner number, and via the q-expansion.
If is a quadratic irrational, then the j-invariant is an algebraic integer of degree , the class number of and the minimal (monic integral) polynomial it satisfies is called the Hilbert class polynomial. Thus if the imaginary quadratic extension has class number 1 (so d is a Heegner number), the j-invariant is an integer.
The q-expansion of j, with its Fourier series expansion written as a Laurent series."
See. Simple!
"Well the Bible says that God exists but then it also alludes to pi being equal to 3 (I Kings 7, 23), so if the equation above is correct then the Bible is wrong and God does not exist." billy
What you have written - if your serious - is not logical.
I am almost sure God does not exist, but your statement does not prove it.
What you have written - if your serious - is not logical.
I am almost sure God does not exist, but your statement does not prove it.
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