# How to avoid an overflow in numpy.exp()

I read a lot on stack Overflow but i still can't understand how avoiding the overflow error. I'am building a Neural network which use the sigmoid function. But I cant go on without converting or finding a workaround for these errors.

``````def activation(x):
return  1/(1+np.exp(-x))

def dactivation(x):
return  activation(x)*(1-activation(x))

def propagateb(self, target, lrate=8.1, momentum=0.1):
deltas = []
error = target - self.layers[-1]
delta = error*dactivation(self.layers[-1])
deltas.append(delta)
for i in range(len(self.shape)-2,0,-1):
delta =np.dot(deltas[0],self.weights[i].T)*dactivation(self.layers[i])
deltas.insert(0,delta)
for i in range(len(self.weights)):
layer = np.atleast_2d(self.layers[i])
delta = np.atleast_2d(deltas[i])
dw = np.dot(layer.T,delta)
self.weights[i] += lrate*dw + momentum*self.dw[i]
self.dw[i] = dw

# Return error
return (error**2).sum()
``````

raise

``````ann.py:5: RuntimeWarning: overflow encountered in exp
return  1/(1+np.exp(-x))
``````

SciPy comes with a function to do that, which won't give you that warning:

``````scipy.special.expit(x)
``````

It seems like the passed-in data must be an integer, although this activation function should return a float. I assume the fix is as simple as

``````return  1./(1.+np.exp(-x))
``````

I would guess that without this change, the code is trying to do integer division, and thereby generating the error.

You have to be careful when you are using numpy integers cause they don't have arbitrary precision as stated here Can Integer Operations Overflow in Python?

For numpy double, that range is `(-1.79769313486e+308, 1.79769313486e+308)`.

Also have a look at this answer which describes it quite well.

The idea is that you should avoid to call `exp(something)` with `something` being too big. So avoid using `exp(x)` when `x >> 0` and avoid using `exp(-x)` when `x << 0`.
1. With x > 0 you can safely use your expression: `1/(1+exp(-x))`
2. For x < 0 you rewrite that expression by multiplying the numerator and the denominator by `exp(x)` which gives `exp(x) / (1+exp(x))`. As you see, no more `exp(-x)` here.
Given x is a matrix, I used `np.exp(np.fmin(x, 0)) / (1 + np.exp(-np.abs(x)))` in my personal experiments here https://github.com/thirionjl/chains/blob/master/chains/operations/activation_ops.py#L42