# Algorithm for logarithmically converting a number to a percentage

I am looking for a way to convert any number to a percentage in the following way:

1. 1.00 is 50%
2. numbers below 1.00 approach 0% logarithmically
3. numbers above 1.00 approach 100% logarithmically.

x > 0. So y needs to approach 0 as x becomes infinitely small on the positive side.

I'm sure this is simple to do, but I can't recall how to do it.

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With infinite limits in either direction? –  Jed Smith Nov 28 '09 at 18:34
Yes - infinite - or at least really big. But such that the difference between "really big" and "infinite" would be negligible. –  Brent Nov 28 '09 at 18:36
some suggestions here: (a) translate percentages to numbers, e.g. "50%" = 0.5, "100%" = 1.0 -- you can always get back to percentages by multiplying by 100. (b) as Stanislav has pointed out, if you mean "asymptotically" rather than "logarithmically", please edit your question accordingly. (c) Please state the input range for your function clearly. Is it 0 to infinity, or -infinity to +infinity? We are having trouble understanding what it is that you want. –  Jason S Nov 28 '09 at 19:25

try `1 / (1 + e^(1-x))`

it's the logistic function shifted by 1 unit

If you want it to approach faster, you can change e to something higher

Edit:

to have f(0) = 0 you could use `1 - 2^(-x)`

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+1 for providing a graph –  Mizipzor Nov 28 '09 at 18:41
Oops -one important point I missed: x > 0. So y needs to approach 0 as x becomes infinitely small on the positive side. –  Brent Nov 28 '09 at 18:51
Well, given that we've misunderstood you, can you draw a graph of what you want and add it to the question? –  Jed Smith Nov 28 '09 at 18:55
Yes, I will add a graph –  Brent Nov 28 '09 at 18:58
default Grapher.app that comes with Mac OS X –  cobbal Nov 28 '09 at 19:02

When you say logarithmically, do you mean asymptotically? If so, then "y needs to approach 0 as x becomes infinitely small on the positive side" just means f(0)=0 if f is continuous. In that case x/(x+1) will work: http://www.wolframalpha.com/input/?i=x%2F%28x%2B1%29

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assuming the desired behavior for y=f(x) is (a) f(0)=0, (b) f(1)=0.5, and (c) lim x->infinity f(x) = 1, I nominate this answer as the best simple answer. I was trying to think of a function involving just add/subtract/multiply/divide that would work but had a brain cramp. –  Jason S Nov 28 '09 at 19:15

how about `y = f(t) = 1 - exp(-t/tau)` ?

For t near 0, y is approximately t/tau. For t approaching infinity, y asymptotically approaches 1.

As for the f(1)=0.5 approach, this can be used to solve for tau = 1/log(2).

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From what you're describing, I'm hearing the graph of x cubed -- very basic, and should be efficient in most languages.

This was graphed with `y=(x-1)^3+1` (transforms to make `(1,1)` the origin). You can, of course, make the results a percentage by simply scaling by 50.

You are, ultimately, trying to have an efficient solution to give you a rough percentage behavior in a programming language and not Mathematica, right?

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This is what I was looking for. Thank you! –  Brent Nov 28 '09 at 19:09
@Brent: this makes no sense. please reword your question to accurately say what it is you want. The above graph approaches 1 at x=1. You mention in your question you want y to approach 1 as x approaches infinity, and you want y = 0.5 when x = 1. –  Jason S Nov 28 '09 at 19:11
Actually, you are right I spoke too soon. This was not what I was looking for, since Y gets greater than 100 –  Brent Nov 28 '09 at 19:15
@Jason: No, he said he wanted a percentage. I'm giving him the curve, it's up to him what units he wants it in. The formula that yields the curve is just that, a formula that yields a curve. He'll have to scale the results, move the origin, etc -- and these are all algebraic transforms. The input does not have to exactly match the desired output in this case -- he's programming (at least I gathered so from "algorithmically"), not handing in a proof. I got him started, that's all. –  Jed Smith Nov 28 '09 at 19:15
@Brent: What the heck do you mean `y` gets greater than 100? I've given you a curve, it's up to you to scale and manipulate to your desired results. You have not expressed your ranges nor constraints in any sensible fashion, and we're working with the data we are given. Scale the expression and don't try to copy and paste it without working with it. I gave you a curve, not a solution. –  Jed Smith Nov 28 '09 at 19:18