I'm experimenting with single-layer perceptrons, and I think I understand (mostly) everything. However, what I don't understand is to which weights the correction (learning rate*error) should be added. In the examples I've seen it seems arbitrary.
Well, it looks like you half answered your own question: its true you correct all of the non-zero weights, you don't correct all by the same amount.
Instead, you correct the weights in proportion to their incoming activation, so if unit X activated really strongly and unit Y activated just a lil bit, and there was a large error, then the weight going from unit X to the output would be corrected far more than unit Y's weights-to-output.
The technical term for this process is called the delta rule, and its details can be found in its wiki article. Additionally, if you ever want to upgrade using to multilayer perceptrons (single layer perceptrons are very limited in computational power, see a discussion of Minsky and Papert's argument against using them here), an analogous learning algorithm called back propogation is discussed here.
Answered my own question.
According to http://intsys.mgt.qub.ac.uk/notes/perceptr.html, "add this correction to any weight for which there was an input". In other words, do not add the correction to weights whose neurons had a value of 0.