# Is this a correct way to find the derivative of the sigmoid function in python?

I came up with this code:

``````def DSigmoid(value):
return (math.exp(float(value))/((1+math.exp(float(value)))**2))
``````

a.) Will this return the correct derivative?
b.) Is this an efficient method?

Friendly regards,
Daquicker

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Sorry if it seems pedantic, but you are defining a function to be the derivative, this function will not return a derivative. It returns a float. Looks correct, and should be efficient enough. – Eric Wilson Sep 27 '11 at 17:37
Guess you are missing some `-` inside both exponentials... – Davide Apr 17 '15 at 19:28

Looks correct to me. In general, two good ways of checking such a derivative computation are:

1. Wolfram Alpha. Inputting the sigmoid function `1/(1+e^(-t))`, we are given an explicit formula for the derivative, which matches yours. To be a little more direct, you can input `D[1/(1+e^(-t)), t]` to get the derivative without all the additional information.

2. Compare it to a numerical approximation. In your case, I will assume you already have a function `Sigmoid(value)`. Taking

`Dapprox = (Sigmoid(value+epsilon) - Sigmoid(value)) / epsilon`

for some small `epsilon` and comparing it to the output of your function `DSigmoid(value)` should catch all but the tiniest errors. In general, estimating the derivative numerically is the best way to double check that you've actually coded the derivative correctly, even if you're already sure about the formula, and it takes almost no effort.

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Thankyou for the confirmation and certainly the second part of your answer is very interesting! – Daquicker Sep 27 '11 at 17:38

In case numerical stability is an issue, there is another possibility: provided that you have a good implementation of the sigmoid available (such as in scipy) you can implement it as:

``````from scipy.special import expit as sigmoid
In my case this solution worked, while the direct implementation caused floating point overflows when computing `exp(-x)`.