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.