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# Does the choice of an activation function and initial weights have any bearing on whether a Neural Network gets stuck in a local minima?

I posted this question yesterday asking if my Neural Network (that I'm training via backpropagation using stochastic gradient descent) was getting stuck in a local minima. The following papers talk about the problem of the local minima in an XOR neural network. The first one says that there isn't a problem of a local minima, whereas as the next paper (written a year later) says that there is a problem of a local minima in a 2-3-1 XOR neural network (as an aside, I'm using a 3-3-1 i.e., bias on the input and hidden layers). Both of these are abstracts (I don't have access to the full paper so I'm unable to read it):

There is also another paper [PDF] that says there isn't a local minima for the simplest XOR network, but it doesn't seem to be talking about a 2-3-1 network.

Now onto my actual question: I couldn't find anything that discussed the choice of the activation function, initial weights and what impact this has on whether the neural network will get stuck in a local minima. The reason I'm asking this question is that in my code I have tried using the standard sigmoid activation function and the hyperbolic tangent activation function. I noticed that in the former, I get stuck only around 20% of the time whereas in the latter I tend to get stuck far more often. I'm also randomizing my weights whenever I first initialize the network and so I'm wondering if a certain set of random weights is more disposed to making my neural network get "stuck".

As far as the activation function is concerned, since the error is eventually related to the output produced by the activation function, I'm thinking that there is an effect (i.e., the error surface changes). However, this is simply based on intuition and I'd prefer a concrete answer (for both points: initial weights and choice of the activation function).

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The random weights given to a Neural Network often immediately restrict the portion of the search space that will be available during learning. This is particularly true when learning rates are small.

However, in the XOR case (using a 3-3-1 topology) there should not be any local minima.

My recommendation is that since the network is so tiny that you should print the edge weights when it seems stuck in a local minima. You should be able to quickly evaluate whether or not the weights appear to be correct and how far away the values are from giving you a perfect network.

One trick that made a large difference for me was instead of updating the weights immediately after each piece of training data was to batch the errors up and update the weights at the end of an epoch. That prevented my network from being swayed early on if the first half of my input data belonged to the same classification bucket.

Which brings me to my next point, are you sure you have an evenly distributed number of training examples? If you provide a neural network with 900 positive classification results but only 100 negative classification results sometimes the network thinks it's just easier to say everything is within the classification group because it only has a 10% error rate if it does. Many learning algorithms are extremely good at finding these kinds of things.

Lastly, the activation function should make little-to-no difference whether or not it hits local minima. The activation function serves primarily as a way to project the domain of reals onto a much smaller known range; (0,1) for sigmoid and (-1,1) for the hyperbolic tangent activation function. You can think of this as a way of enforcing equality across all of your learned features at a given neural layer (a.k.a. feature scaling). Since the input domain is not known before hand it's not as simple as regular feature scaling for linear regression and thusly activation functions must be used but it is otherwise compensated for when computing errors during back propagation.

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The training examples I'm using are `[(0,0), (0,1), (1,0), (1,1)]` to output to `[0, 1, 1, 0]`. By "distribute", do you mean that I should be presenting these input patterns in a random manner to the network? Also, I noticed that I wasn't getting stuck when I increased the number of neurons in the hidden layer to 4. I will modify my code to print out the weights to I can see what they are. I also like the idea of batching up the errors. Do you mean that you add up the errors? Or do you keep them in an array and update the weights at the end of the epoch by iterating through the error array? – Vivin Paliath Nov 9 '11 at 15:53
I do mean effective randomized presentation of training samples to the NN. You could try samples that have even output values like [0,1,0,1]. If you batch the errors then you don't have to worry at all about the ordering. To batch up errors and update the weights once per epoch you still do the back-propagation step to calculate the error values, but when you update each weight you should use the average error (Sum weights / total training samples). – Nate Nov 9 '11 at 17:28
Oh, so basically I should shuffle the input patterns. The batch update also makes sense. I guess I will just add up the errors and once I am done with the epoch I will divide it by the number of iterations and then use that value for the backpropagation. Thanks! This makes sense. – Vivin Paliath Nov 9 '11 at 17:59