# How to update the bias in neural network backpropagation?

Could someone please explain to me how to update the bias throughout backpropagation?

I've read quite a few books, but can't find bias updating!

I understand that bias is an extra input of 1 with a weight attached to it (for each neuron). There must be a formula.

• That's a big question with a regrettably large answer. This is a decent starting point: ftp.sas.com/pub/neural/FAQ2.html#A_bias – msw Sep 23 '10 at 2:36
• Train this weight like all the others using gradient descent – pberkes Sep 23 '10 at 13:47
• Bias term is required, a bias value allows you to shift the activation function(sigmoid function) to the left or right. The weights used in bias term will be changed in back propagation algorithm and will be optimized using gradient descent or advanced optimization technique like fminunc function in Octave/Matlab. – Goyal Vicky Dec 7 '17 at 10:38

Following the notation of Rojas 1996, chapter 7, backpropagation computes partial derivatives of the error function `E` (aka cost, aka loss)

``````∂E/∂w[i,j] = delta[j] * o[i]
``````

where `w[i,j]` is the weight of the connection between neurons `i` and `j`, `j` being one layer higher in the network than `i`, and `o[i]` is the output (activation) of `i` (in the case of the "input layer", that's just the value of feature `i` in the training sample under consideration). How to determine `delta` is given in any textbook and depends on the activation function, so I won't repeat it here.

These values can then be used in weight updates, e.g.

``````// update rule for vanilla online gradient descent
w[i,j] -= gamma * o[i] * delta[j]
``````

where `gamma` is the learning rate.

The rule for bias weights is very similar, except that there's no input from a previous layer. Instead, bias is (conceptually) caused by input from a neuron with a fixed activation of 1. So, the update rule for bias weights is

``````bias[j] -= gamma_bias * 1 * delta[j]
``````

where `bias[j]` is the weight of the bias on neuron `j`, the multiplication with 1 can obviously be omitted, and `gamma_bias` may be set to `gamma` or to a different value. If I recall correctly, lower values are preferred, though I'm not sure about the theoretical justification of that.

• Do people include the bias (`1`) at layer `l` as this layer's activation? I mean if so, then the update of weights in layer `l`, including the weights for its bias can be written as a single formula: `w(l) -= gamma * dot( delta(l+1), o(l))`, am I right? – Jason Jul 19 '17 at 2:02

The amount you change each individual weight and bias will be the partial derivative of your cost function in relation to each individual weight and each individual bias.

``````∂C/∂(index of bias in network)
``````

Since your cost function probably doesn't explicitly depend on individual weights and values (Cost might equal (network output - expected output)^2, for example), you'll need to relate the partial derivatives of each weight and bias to something you know, i.e. the activation values (outputs) of neurons. Here's a great guide to doing this:

https://medium.com/@erikhallstrm/backpropagation-from-the-beginning-77356edf427d

This guide states how to do these things clearly, but can sometimes be lacking on explanation. I found it very helpful to read chapters 1 and 2 of this book as I read the guide linked above:

http://neuralnetworksanddeeplearning.com/chap1.html (provides essential background for the answer to your question)