中文

General Loss Bounds for Universal Sequence Prediction

人工智能 2011-11-09 v2 机器学习 统计理论 统计理论

摘要

The Bayesian framework is ideally suited for induction problems. The probability of observing xtx_t at time tt, given past observations x1...xt1x_1...x_{t-1} can be computed with Bayes' rule if the true distribution μ\mu of the sequences x1x2x3...x_1x_2x_3... is known. The problem, however, is that in many cases one does not even have a reasonable estimate of the true distribution. In order to overcome this problem a universal distribution ξ\xi is defined as a weighted sum of distributions μi\inM\mu_i\inM, where MM is any countable set of distributions including μ\mu. This is a generalization of Solomonoff induction, in which MM is the set of all enumerable semi-measures. Systems which predict yty_t, given x1...xt1x_1...x_{t-1} and which receive loss lxtytl_{x_t y_t} if xtx_t is the true next symbol of the sequence are considered. It is proven that using the universal ξ\xi as a prior is nearly as good as using the unknown true distribution μ\mu. Furthermore, games of chance, defined as a sequence of bets, observations, and rewards are studied. The time needed to reach the winning zone is bounded in terms of the relative entropy of μ\mu and ξ\xi. Extensions to arbitrary alphabets, partial and delayed prediction, and more active systems are discussed.

关键词

引用

@article{arxiv.cs/0101019,
  title  = {General Loss Bounds for Universal Sequence Prediction},
  author = {Marcus Hutter},
  journal= {arXiv preprint arXiv:cs/0101019},
  year   = {2011}
}

备注

8 two-column pages, LaTeX2e