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I've been reading some things on neural networks and I understand the general principle of a single layer neural network. I understand the need for aditional layers, it provides more computation power, but why are nonlinear activation functions used?

This question is followed by this one: What is a derivative of the activation function used for in backpropagation?.

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5 Answers 5

up vote 20 down vote accepted

The purpose of the activation function is to introduce non-linearity into the network

non-linear means that the output cannot be reproduced from a linear combination of the inputs (which is not the same as output that renders to a straight line--the word for this is affine).

another way to think of it: without a non-linear activation function in the network, a NN, no matter how many layers it had would behave just like a single perceptron (because summing these layers just give you another linear function-see definition just above).

>>> in_vec = NP.random.rand(10)
>>> in_vec
  array([ 0.94,  0.61,  0.65,  0.  ,  0.77,  0.99,  0.35,  0.81,  0.46,  0.59])

>>> # common activation function, hyperbolic tangent
>>> out_vec = NP.tanh(in_vec)
>>> out_vec
 array([ 0.74,  0.54,  0.57,  0.  ,  0.65,  0.76,  0.34,  0.67,  0.43,  0.53])

A common activation function used in backprop (hyperbolic tangent) evaluated from -2 to 2:

enter image description here

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Why would we want to eliminate linearity? – jcora Mar 20 '12 at 10:02
If the data we wish to model is non-linear then we need to account for that in our model. – doug Mar 20 '12 at 10:10
OK, I understand it now, thanks! – jcora Mar 20 '12 at 20:42
One sentence answer: <<no matter how many layers would behave just like a single perceptron (because linear functions added together just give you a linear function).>>. Nice! – Parag S. Chandakkar May 23 at 0:57
This is a little misleading - as eski mentioned, rectified linear activation functions are extremely successful, and if our goal is just to model/approximate functions, eliminating non-linearity at all steps isn't necessarily the right answer. With enough linear pieces, you can approximate almost any non-linear function to a high degree of accuracy. I found this a good explanation of why rectified linear units work:… – tegan Aug 3 at 15:20

It's not at all a requirement. In fact, the rectified linear activation function is very useful in large neural networks. Computing the gradient is much faster, and it induces sparsity by setting a minimum bound at 0.

See the following for more details:

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The rectified linear activation function is also non-linear (despite its name). It is just linear for positive values – Plankalkül Aug 21 at 9:08
You're technically correct, it's not linear across the entire domain, specifically at x=0 (it is linear for x < 0 actually, since f(x) = 0 is a linear function). It's also not differentiable so the gradient function isn't fully computable either, but in practice these technicalities are easy to overcome. – eski Aug 21 at 17:00

"The present paper makes use of the Stone-Weierstrass Theorem and the cosine squasher of Gallant and White to establish that standard multilayer feedforward network architectures using abritrary squashing functions can approximate virtually any function of interest to any desired degree of accuracy, provided sufficently many hidden units are available." (Hornik et al., 1989,

A squashing function is for example a nonlinear activation function that maps to [0,1] like the sigmoid activation function.

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As I remember - sigmoid functions are used because their derivative that fits in BP algorithm is easy to calculate, something simple like f(x)(1-f(x)). I don't remember exactly the math. Actually any function with derivatives can be used.

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The function still wants to be monotonically increasing, as I recall. So, not any function. – Novak Mar 20 '12 at 19:01
Yes, you're right; Didn't remembered exactly – Anton Mar 21 '12 at 8:15

A layered NN of several neurons can be used to learn linearly inseparable problems. For example XOR function can be obtained with two layers with step activation function.

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