I'm looking into using compression as a way to measure the relation of a document to a corpus of documents. In doing so I've found a strange result when using bzip2; len(compress(corpus)) > len(compress(corpus + new_document)). Should this be the case with a practical compression algorithm and is this theoretically possible when looking at the Kolmogorov complexity of data? (the idea is to use a compression algorithm to approximate the complexity of the data)
Yes, it should be the case with a practical compression algorithm, and is theoretically possible with Kolmogorov complexity. The easiest way to explain why is with an example. Suppose the following:
Then:
So Edit It has been mentioned in another answer that runlength encoding is not Turing complete and so cannot be used for Kolmogorov complexity. While this is true, using a Turing language you can implement an encoding of runlength in whatever description language you choose to use, with the same result, so the example still holds valid. 


Reallife compression algorithms have quirks like this but they only provide for a very crude approximation anyway. And as for whether it can happen in theory, probably, but the difference isn't significant. Let's assume you've got two strings, x and y, where x is a prefix of y. Let's say for example that x = "asdfasdfasdfasdfasdfasdfasdfasdfasdf" y = "asdfasdfasdfasdfasdfasdfasdfasdfasdf23452345234523452344523452452345234524345234" Let's assume furthermore that D is the shortest description of y. (I.e. K(y) = D) In this case, x can be described as "the number described by D minus 46 characters", which is longer than D but only by a small constant and a logarithmic factor (the number of characters in the rest of the instructions basically). There might even be a shorter description of x but we know that at worst, K(x) <= K(y)+log(yx) However, you have to bear in mind that theoretical Kolmogorov complexity is incomputable and constant differences mean nothing in this field. (N.b.: The RLE example above isn't valid as RLE isn't a Turing complete language, therefore it can't be used as a description language for Kolmogorov complexity.) 

