# Back propagation Error Function

I have a quick question regarding back propagation. I am looking at the following:

http://www4.rgu.ac.uk/files/chapter3%20-%20bp.pdf

In this paper it says calculate the error the neuron error as:

Error = Output(i) * (1 - Output(i)) * (Target(i) - Output(i))

I have put the part of the equation that I don't understand in bold. In the paper, it says that the Output(i) * (1 - Output(i)) term is needed because of the sigmoid function - but I still don't understand why this would be nessecary ? What would be wrong with using ...

``````Error = abs(Output(i) - Target(i))
``````

... as the error function regardless of the neuron activation/transfer function ?

Many thanks

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The reason you need this is that you are calculating the derivative of the error function with respect to the neuron's inputs.

When you take the derivative via the chain rule, you need to multiply by the derivative of the neuron's activation function (which happens to be a sigmoid)

Here's the important maths (apologies for the formatting...):

Calculate derivative of error on the neuron's inputs via the chain rule:

``````E = -(target - output)^2

dE/dinput = dE/doutput * doutput/dinput
``````

Work out dinput/doutput:

``````output = sigmoid (input)

doutput/dinput = output * (1 - output)    (derivative of sigmoid function)
``````

therefore:

``````dE/dinput = 2 * (target - output) * output * (1 - output)
``````
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Thanks for the clarification - In the paper i refer to it says that this is needed because of the sigmoid function. If I was using any other function, would I still need to do this ? –  Sherlock Jul 24 '12 at 13:27
You'd still need to do this, but the derivative part would be different according to the function you use. In the most trivial case, doutput/dinput is just 1 if you have a linear function. –  mikera Jul 24 '12 at 13:46
You got +1 for not using retarded math formulas and instead showing how it would look like in code. As it should be on Stack Overflow. –  Karl Morrison Nov 20 '14 at 12:59

The choice of the sigmoid function is by no means arbitrary. Basically you are trying to estimate the conditional probability of a class label given some sample. If you take the absolute value, you are doing something different, and you will get different results.

For a practical introduction in the topic I would recommend you to check out the online Machine Learning course by Prof. Andrew Ng

https://www.coursera.org/course/ml

and the book by Prof. Christopher Bishop for an in depth study on the topic

http://www.amazon.com/Neural-Networks-Pattern-Recognition-Christopher/dp/0198538642/ref=sr_1_1?ie=UTF8&qid=1343123246&sr=8-1&keywords=christopher+bishop+neural+networks

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