Posts tagged with: ReLU neurons

Neural Networks in Julia – Hyperbolic tangent and ReLU neurons

get the code from here

Our goal for this post is to introduce and implement new types of neural network nodes using Julia language. These nodes are called ‘new’ because this post loosely refers to the existing code.

So far we introduced sigmoid and linear layers and today we will describe another two types of neurons. First we will look at hyperbolic tangent that will turn out to be similar (in shape at least) to sigmoid. Then we will focus on ReLU (rectifier linear unit) that on the other hand is slightly different as it in fact represents non-differentiable function. Both yield strong practical implications (with ReLU being considered more important recently – especially when considered in the context of networks with many hidden layers).

What is the most important though, adding different types of neurons to neural network changes the function it represents and so its expressiveness, lets then emphasize this as the main reason they are being added.

Hyperbolic tangent layer

From the biological perspective, the purpose of sigmoid activation function as single node ‘crunching function’ is to model passing an electrical signal from one neuron to another in brain. Strength of that signal is expressed by a number from \((0,1)\) and it relies on signal from the input neurons connected to the one under consideration. Hyperbolic tangent is yet another way of modelling it.

Let’s first take a look at the form of hyperbolic tangent:

f(x) = \frac{\mathrm{e}^x – \mathrm{e}^{-x}}{\mathrm{e}^x + \mathrm{e}^{-x}}
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