# Normalizing a random unending unknown series?

I have an unending series with no equation, and is random, something like this,

``````   X = 1, 456, 555, 556, 557, 789 ...
``````

Note that I'm getting this list as a stream, and I do not know future values, and I do not know min and max of `X`.

How do I find out the inverted normal `N(X)` for any `x in X`, such that,

`N(x) --> 0` if `x --> inf`

`N(x) --> 1` if `x --> 0`

Read that as, the greater the `x` is the closer it should be to `0`, the smaller the `x` is the closer it should be to `1`.

How can I achieve such a transformation?

I tried the following:

``````#python
def invnorm(x):
denom = 1 + math.exp(-x)
return 2 - (2/denom)

invnorm(200)
Out: 0.0

invnorm(20)
Out: 4.1223073843355e-09

invnorm(2)
Out: 0.23840584404423537

invnorm(1)
Out: 0.5378828427399902
``````

Somehow that doesn't give a satisfactory result as my range goes on to a large number, and `200` itself gives `0` and my range will be skewed towards `0`.

• Are the inputs guaranteed to be positive integers? – user2357112 Jan 22 '14 at 7:26
• A very interesting question and I regret I don't have time to ponder upon it right now. Maybe try math.stackexchange.com if you don't get satisfactory answers here as this is a Mathematics problem, probably even more than computing IMHO. Good luck. – Aleksander Lidtke Jan 22 '14 at 7:42
• Your question is underspecified. `N(x)=(x>0)?1:0` satisfies your requirements, as far as I can tell. – Anony-Mousse Jan 22 '14 at 8:47
• The problem with your original function is that `e^{-x}` decreases very quickly, so that by the time you get to `x=200`, it's essentially zero. The accepted solution fixes that problem by finding something that decreases more slowly. – Teepeemm Jan 22 '14 at 13:51

OK, so you're basically looking for a continuous monotone function N: [0,∞) → (0,1] such that:

• limx → 0 N(x) = 1, and
• limx → ∞ N(x) = 0.

In that case, the "obvious" choice would be N(x) = 1 / (x + 1), or, in Python:

``````def invnorm (x):
return 1.0 / (x + 1)
``````

Of course, there are also infinitely many other functions that satisfy these criteria, like N(x) = 1 / (x + 1)a for any positive real number a.

Yet another "natural" choice would be N(x) = ex, or, in Python:

``````def invnorm (x):
return math.exp(-x)
``````

This can also be rescaled to N(x) = bx for any real number b > 1 while still satisfying your requirements.

And of course, if we relax the monotonicity requirement (which I just assumed, even though you did not state it explicitly), even weirder functions like Abhishek Bansal's N(x) = sin(x) / x will qualify.

`1 - X / M`, where `M` is the expected largest value (could be `4294967295.` for integer `X`'s).

• Actually, you didn't provide enough details to allow a reasonable answer. – Yves Daoust Jan 22 '14 at 8:20