# sigmoid function in python

I am trying to understand why my sigmoid function when the input is 37, it output 1. the sigmoid function:

``````import math

def sigmoid(x):
return 1 / (1 + math.e ** -x)
``````

I am not good in math but I think there should never be a moment where the f(x) is equal to 1 right? maybe it is because the e constant isnt precise enough however my real problem is I want to map a number between 0 and 1 to what is x when f(x) is 0 and what x is when f(x) is 1. my map function:

``````def p5map(n, start1, stop1, start2, stop2):
return ((float(n)-start1)/(stop1-start1))*(stop2-start2)+start2
``````

so for exemple I want to do

``````p5map(y, 0, 1, -37, 37)
``````

where the y would be f(x) in the sigmoid curve and -37 and 37 would be where f(x) is 0 and 1 respectively. using -37 and 37 would not work for me so what I am asking is why is it 37 and how can I fix that so it is between -1 and 1 for exemple

• It's simple: `math.e ** -37` approximates to 0, evaluating the whole expression to `1 / 1` which is 1.
– cs95
Jun 9, 2017 at 21:12
• But use `math.exp(x)` rather than `math.e ** x`. Jun 9, 2017 at 21:15

You are working with regular floating point numbers, which can hold only 15 or 16 significant digits. When you evaluate `math.e**-37` the result is

``````8.533047625744083e-17
``````

When you add that to one, you may want to get

``````1.00000000000000008533047625744083
``````

but the computer in effect removes all but the first 16 digits and gives

``````1.000000000000000
``````

which is simply `1`. In fact, adding `1e-16` to `1` just gives `1`. You do get something other than one when you add `1e-15` but that is larger than what you are trying.

There are several ways to get what you want. One way is to use Python's decimal module, which adds many more significant digits to your numbers and calculations, and you can add as many as you want. Using decimal,

``````from decimal import Decimal
print(1 / (1 + Decimal(-37).exp()))
``````

you get

``````Decimal('0.9999999999999999146695237430')
``````

and the resulting sigmoid function `1/(1+D(37).exp())` for `-37` gives

``````Decimal('8.533047625744065066149031992E-17')
``````

which is not zero.

Another solution is to use another sigmoid function, different from the one you use, that approaches 1 more slowly than yours does. One that approaches `1` slowly is

``````0.5 * (1 + x / (1 + abs(x)))
``````

Doing that to `37` yields

``````0.986842105263158
``````

which is far from `1`, and the result for `-37` is

``````0.01315789473684209
``````