# Is there a machine learning algorithm which successfully learns the parity function?

The parity function is a function from a vector of n bits and outputs 1 if the sum is odd and 0 otherwise. This can be viewed as a classification task, where the n input are the features.

Is there any machine learning algorithm which would be able to learn this function? Clearly random decision forests would not succeed, since any strict subset of features has no predictive power. Also, I believe no neural network of a fixed depth would succeed, since computing the parity function is not in the complexity class AC0.

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For fixed n, wouldn't a two-layer perceptron with a sufficiently large hidden layer be enough? –  larsmans Feb 28 '12 at 16:50
Well, yes it would. If one has one node in the hidden layer for every combination 00011110101 of input bits it is trivially possible. The number of hidden nodes will then grow exponentially with n. –  Petter Mar 2 '12 at 15:48
Usually you should use around 2*n hidden nodes in your MLP with one hidden layer and it should work. Standard backpropagation is an outdated optimization algorithm for ANNs. I would suggest Levenberg-Marquardt, Conjugate Gradient, Quickprop or RProp instead. –  alfa Mar 3 '12 at 21:24
alfa: right, but in this case I don't think polynomially many hidden layer nodes will work. –  Petter Mar 4 '12 at 14:33

Polynomial SVMs can do this. Encode zeros as 1 and ones as -1. For n variables (bits), you need a polynomial kernel of degree n. When the kernel is computed, it also implicitly computes the value x1 * x2 * ... * xn (where xi is the i-th input variable). If the result is -1, you have an odd number of ones, otherwise you have an even number of ones.

If I'm not mistaken, Neural Networks should also be able to compute it. As far as I remember, Neural Networks with 2 hidden layers and sigmoid units are able to learn any arbitrary function.

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Good point about the polynomial SVMs! A NN with one hidden layer is trivially able to compute any Boolean function, but then the hidden layers would have to grow exponentially in n. –  Petter Mar 2 '12 at 15:41
I guess I was under the false impression that NNs were somehow equivalent to Boolean circuits. –  Petter Mar 2 '12 at 15:43