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Wisecrack
5y

More masturbation with numbers.

If you take some product p,
and do

√p**(1/p)

and it's factors

a**(1/p)

and

b**(1/p)

you might find something interesting.

Take for example

a=21977
b=43331
p=a*b=952285387

(√p)**(1/p) = 1.0000000108551363

a**(1/p) = 1.0000000104986928
b**(1/p) = 1.0000000112115799

More often then not, a, b, or both, will share one or two of the most significant digits in the mantissa, as the root of p.

It doesn't always work, but it seems to be true more often than you might expect.

This is probably obvious in hindsight but I still think it's cool.

In some instances if you then do, say
sqrt(log(p, 1.000000010)), it comes pretty close to the original factors, but thats really hit or miss.

random

math
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Comments
  • 4
    5y
    That’s a beautiful pattern. Does it have any practical applications?
  • 2
    5y
    @rutee07

    gang gang. It's elementary school up in this bitch!

    @Diactoros

    Hell if I know. I can barely math at all.

    Edit: I used python nipple operate (**), instead of tiny hat operator (^)

    Derp.
  • 3
    5y
    @Wisecrack Anyone with a math background knew what you meant. I’m not python literate though so I did have a moment of confusion. Interesting find.
  • 2
    5y
    @Diactoros Whats your background in math, if you don't mind me asking? It's exciting to meet people who are familiar with the subject and maybe enjoy it, and not just read anonymous posts on quora/wikipedia/textbooks written by strangers.
  • 1
    5y
    Masturbation? This is torture
  • 1
    5y
    Does this still apply when a and b differ by orders of magnitude?
  • 1
    5y
    @Lor-inc

    Haven't checked but now I have to.

    They tend to share 1 or 2 digits in the mantissa, and when they don't, those digits at least tend to be in order, e.x.

    ...15..

    ...16...

    ...17..

    Which makes sense if assuming a is the lower factor of p and b is the higher factor. (assuming p only has only four factors, a, b, p, and 1), because a/√p == b/√p
  • 0
    5y
    Addendum

    I was actually hoping what I could do was use it as a good starting point to factor p, by solving for the base of the logarithm.

    Where a or b (p's factors) are the respective bases.

    w**(1/w)

    a**(1/w)

    b**(1/w)

    also tend to share digits, especially where

    w**(1/p) fails.
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