Predictions are usually reduced to symbol rankings. Each symbol (a letter, bit or any other amount of data) is ranked before it is compressed, and the ranking system determines the corresponding codeword (and therefore the compression rate). In many compression algorithms, the ranking is equivalent to probability mass function estimation. Given the previous letters (or given a context), each symbol is assigned with a probability. For instance, in
arithmetic coding the symbols are ranked by their probabilities to appear after previous symbols, and the whole sequence is compressed into a single fraction that is computed according to these probabilities. The number of previous symbols,
n, determines the order of the PPM model which is denoted as PPM(
n). Unbounded variants where the context has no length limitations also exist and are denoted as
PPM*. If no prediction can be made based on all
n context symbols, a prediction is attempted with
n − 1 symbols. This process is repeated until a match is found or no more symbols remain in context. At that point a fixed prediction is made. Much of the work in optimizing a PPM model is handling inputs that have not already occurred in the input stream. The obvious way to handle them is to create a "never-seen" symbol which triggers the
escape sequence. But what probability should be assigned to a symbol that has never been seen? This is called the zero-frequency problem. One variant uses the
Laplace estimator, which assigns the "never-seen" symbol a fixed
pseudocount of one. A variant called PPMd increments the pseudocount of the "never-seen" symbol every time the "never-seen" symbol is used. (In other words, PPMd estimates the probability of a new symbol as the ratio of the number of unique symbols to the total number of symbols observed). == Implementation ==