Variable-order Markov model

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In the mathematical theory of stochastic processes, variable-order Markov (VOM) models are an important class of models that extend the well known Markov chain models. In contrast to the Markov chain models, where each random variable in a sequence with a Markov property depends on a fixed number of random variables, in VOM models this number of conditioning random variables may vary based on the specific observed realization.

This realization sequence is often called the context; therefore the VOM models are also called context trees.[1] VOM models are nicely rendered by colorized probabilistic suffix trees (PST).[2] The flexibility in the number of conditioning random variables turns out to be of real advantage for many applications, such as statistical analysis, classification and prediction.[3][4][5]

Example

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Consider for example a sequence of random variables, each of which takes a value from the ternary alphabet {a, b, c}. Specifically, consider the string constructed from infinite concatenations of the sub-string aaabc: aaabcaaabcaaabcaaabc…aaabc.

The VOM model of maximal order 2 can approximate the above string using only the following five conditional probability components: Pr(a | aa) = 0.5, Pr(b | aa) = 0.5, Pr(c | b) = 1.0, Pr(a | c)= 1.0, Pr(a | ca) = 1.0.

In this example, Pr(c | ab) = Pr(c | b) = 1.0; therefore, the shorter context b is sufficient to determine the next character. Similarly, the VOM model of maximal order 3 can generate the string exactly using only five conditional probability components, which are all equal to 1.0.

To construct the Markov chain of order 1 for the next character in that string, one must estimate the following 9 conditional probability components: Pr(a | a), Pr(a | b), Pr(a | c), Pr(b | a), Pr(b | b), Pr(b | c), Pr(c | a), Pr(c | b), Pr(c | c). To construct the Markov chain of order 2 for the next character, one must estimate 27 conditional probability components: Pr(a | aa), Pr(a | ab), , Pr(c | cc). And to construct the Markov chain of order three for the next character one must estimate the following 81 conditional probability components: Pr(a | aaa), Pr(a | aab), , Pr(c | ccc).

In practical settings there is seldom sufficient data to accurately estimate the exponentially increasing number of conditional probability components as the order of the Markov chain increases.

The variable-order Markov model assumes that in realistic settings, there are certain realizations of states (represented by contexts) in which some past states are independent from the future states; accordingly, "a great reduction in the number of model parameters can be achieved."[1]

Definition

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Let A be a state space (finite alphabet) of size |A|.

Consider a sequence with the Markov property x1n=x1x2xn of n realizations of random variables, where xiA is the state (symbol) at position i (1in), and the concatenation of states xi and xi+1 is denoted by xixi+1.

Given a training set of observed states, x1n, the construction algorithm of the VOM models[3][4][5] learns a model P that provides a probability assignment for each state in the sequence given its past (previously observed symbols) or future states.

Specifically, the learner generates a conditional probability distribution P(xis) for a symbol xiA given a context sA*, where the * sign represents a sequence of states of any length, including the empty context.

VOM models attempt to estimate conditional distributions of the form P(xis) where the context length |s|D varies depending on the available statistics. In contrast, conventional Markov models attempt to estimate these conditional distributions by assuming a fixed contexts' length |s|=D and, hence, can be considered as special cases of the VOM models.

Effectively, for a given training sequence, the VOM models are found to obtain better model parameterization than the fixed-order Markov models that leads to a better variance-bias tradeoff of the learned models.[3][4][5]

Application areas

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Various efficient algorithms have been devised for estimating the parameters of the VOM model.[4]

VOM models have been successfully applied to areas such as machine learning, information theory and bioinformatics, including specific applications such as coding and data compression,[1] document compression,[4] classification and identification of DNA and protein sequences,[6] [1][3] statistical process control,[5] spam filtering,[7] haplotyping,[8] speech recognition,[9] sequence analysis in social sciences,[2] and others.

See also

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References

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  8. ^ Browning, Sharon R. "Multilocus association mapping using variable-length Markov chains." The American Journal of Human Genetics 78.6 (2006): 903–913.
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