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This is a follow-on question to this post. For a given neuron, I'm unclear as to how to take a partial derivative of its error and the partial derivative of it's weight.

Working from this web page, it's clear how the propogation works (although I'm dealing with Resilient Propagation). For a Feedforward Neural Network, we have to 1) while moving forwards through the neural net, trigger neurons, 2) from the output layer neurons, calculate a total error. Then 3) moving backwards, propogate that error by each weight in a neuron, then 4) coming forwards again, update the weights in each neuron.

Precisely though, these are the things I don't understand.

A) For each neuron, how do you calculate the partial derivative (definition) of the error over the partial derivative of the weight? My confusion is that, in calculus, a partial derivative is computed in terms of an n variable function. I'm sort of understanding ldog and Bayer's answers in this post. And I even understnad the chain rule. But it doesn't gel when I think, precisely, of how to apply it to the results of a i) linear combiner and ii) sigmoid activation function.

B) Using the Resilient propogation approach, how would you change the bias in a given neuron ? Or is there no bias or threshold in a NN using Resilient Propagation training?

C) How do you propagate a total error if there are two or more output neurons ? Does the total-error * neuron weight happen for each output neuron value?


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1 Answer 1

Not 100% sure on the other points, but I can answer B at this moment:

B)The bias is updated based on the direction of the partial derivative, and not on the magnitude. the size of the weight update is increased if the direction remains unchanged for consecutive iterations. oscillating directions will reduce the size of update. http://nopr.niscair.res.in/bitstream/123456789/8460/1/IJEMS%2012(5)%20434-442.pdf

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