I want to know whether Artificial Neural Networks can be applied to discrete values inputs? I know they can be applied to continuous valued inputs, but can they be applied to discrete valued ones? Also, will perform well for discrete valued inputs?

Well, good question let me say! First of all let me answer directly yes to your question! The answer implies to consider few aspects about the use and the implementation of the network itself. Than let me explain why:
As a plus you could consider the use of "step" transfer function, instead of "tansigmoid", between layers just to strenght and mimic a sort of digitization forcing the output to be just 0 or 1. But you should reconsider also the starting normalization as well as the use of well tuned thresholds. NB: this latter trick is not really necessary but could give some secondary benefits; maybe test it in a second stage of your development and look at the differences. PS: Just let me suggest something that should apply to your issue; if you would be smart take into account the use of some fuzzy logic on your learning algorithm ;) Cheers! 


Yes, artificial neural networks may be applied to data featuring discretevalue input variables. In the most commonly used neural network architectures (which are numeric), discrete inputs are typically represented by a series of dummy variables, just as in statistical regression. Also, as with regression, one less than the number of distinct values dummy variables is needed. There are other methods, but this is the most straightforward. 


I'm late on this question, but this may help someone. Say you have a categorical output variable, for example 3 different categories (0, 1 and 2), outputs
then becomes
A possible NN output result is
Then your NN hill have 3 output nodes in this case, so take the max value. To improve this, use entropy as a error measure and a softmax activation on the output layer, so that the outputs sum up to 1. 


The purpose of a neural network is to approximate complicated functions by interpolating samples. As such, they tend to be a poor fit for discrete data, unless that data can be expressed by thresholding a continuous function. Depending on your problem, there are likely to be much more effective learning methods. 

