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I am trying to build a neural network from scratch. Across all AI literature there is a consensus that weights should be initialized to random numbers in order for the network to converge faster.

But Why are neural networks initial weights initialized as random numbers?

I had read somewhere that this is done to "break the symmetry" and this makes the neural network learn faster. How does breaking the symmetry make it learn faster?

Would'nt initializing the weights to 0 be a better idea? That way the weights would be able to find their values (whether positive or negative) faster?

Is there some other underlying philosophy behind randomizing the weights apart from hoping that they would be near their optimum values when initialized?

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2 Answers

Breaking symmetry is essential here, and not for the reason of performance. Imagine first 2 layers of multilayer perceptron (input and hidden layers):

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During forward propagation each unit in hidden layer gets signal:

enter image description here

That is, each hidden unit gets sum of inputs multiplied by the corresponding weight.

Now imagine that you initialize all weights to the same value (e.g. zero or one). In this case, each hidden unit will get exactly the same signal. E.g. if all weights are initialized to 1, each unit gets signal equal to sum of inputs (and outputs sigmoid(sum(inputs))). If all weights are zeros, which is even worse, every hidden unit will get zero signal. No matter what was the input - if all weights are the same, all units in hidden layer will be the same too.

This is the main issue with symmetry and reason why you should initialize weights randomly (or, at least, with different values). Note, that this issue affects all architectures that use each-to-each connections.

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The answer is pretty simple. The basic training algorithms are greedy in nature - they do not find the global optimum, but rather - "nearest" local solution. As the result, starting from any fixed initialization biases your solution towards some one particular set of weights. If you do it randomly (and possibly many times) then there is much less probable that you will get stuck in some weird part of the error surface.

The same argument applies to other algorithms, which are not able to find a global optimum (k-means, EM, etc.) and does not apply to the global optimization techniques (like SMO algorithm for SVM).

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So, it is not guaranteed that it will not get stuck in local minima just by randomizing? But after multiple runs with different randomized weights it might get the global minimum? –  Shayan RC Nov 18 '13 at 3:57
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There is no guarantee, but multiple initializations can help at least get near the true optimum. –  lejlot Nov 18 '13 at 7:35
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