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Stochastic scrabble: large deviations for sequences with scores

Published online by Cambridge University Press:  14 July 2016

Richard Arratia ,
Pricilla Morris  and
Michael S. Waterman
Richard Arratia
Affiliation:
University of Southern California
Pricilla Morris
Affiliation:
University of Southern California
Michael S. Waterman
Affiliation:
University of Southern California
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Abstract

A derivation of a law of large numbers for the highest-scoring matching subsequence is given. Let Xk, Yk be i.i.d. q=(q(i))iS letters from a finite alphabet S and v=(v(i))iS be a sequence of non-negative real numbers assigned to the letters of S. Using a scoring system similar to that of the game Scrabble, the score of a word w=i1 · ·· im is defined to be V(w)=v(i1) + · ·· + v(im). Let Vn denote the value of the highest-scoring matching contiguous subsequence between X1X2 · ·· Xn and Y1Y2· ·· Yn. In this paper, we show that Vn/K log(n) → 1 a.s. where KK(q,v). The method employed here involves ‘stuttering’ the letters to construct a Markov chain and applying previous results for the length of the longest matching subsequence. An explicit form for β ∊Pr(S), where β (i) denotes the proportion of letter i found in the highest-scoring word, is given. A similar treatment for Markov chains is also included.

Implicit in these results is a large-deviation result for the additive functional, H ≡ Σn < τv(Xn), for a Markov chain stopped at the hitting time τ of some state. We give this large deviation result explicitly, for Markov chains in discrete time and in continuous time.

Keywords

LARGE DEVIATIONSADDITIVE FUNCTIONALSDNA SEQUENCE MATCHINGMARKOV CHAINS
Type
Research Papers
Information
Journal of Applied Probability , Volume 25 , Issue 1 , March 1988 , pp. 106 - 119
Copyright
Copyright © Applied Probability Trust 1988 

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Footnotes

Research supported by the System Development Foundation,

the National Science Foundation,

§

the Institute of Mathematics and its Applications and

††

the National Institutes of Health.

References

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