English

Estimating Mutual Information

Statistical Mechanics 2009-11-10 v1 Disordered Systems and Neural Networks

Abstract

We present two classes of improved estimators for mutual information M(X,Y)M(X,Y), from samples of random points distributed according to some joint probability density μ(x,y)\mu(x,y). In contrast to conventional estimators based on binnings, they are based on entropy estimates from kk-nearest neighbour distances. This means that they are data efficient (with k=1k=1 we resolve structures down to the smallest possible scales), adaptive (the resolution is higher where data are more numerous), and have minimal bias. Indeed, the bias of the underlying entropy estimates is mainly due to non-uniformity of the density at the smallest resolved scale, giving typically systematic errors which scale as functions of k/Nk/N for NN points. Numerically, we find that both families become {\it exact} for independent distributions, i.e. the estimator M^(X,Y)\hat M(X,Y) vanishes (up to statistical fluctuations) if μ(x,y)=μ(x)μ(y)\mu(x,y) = \mu(x) \mu(y). This holds for all tested marginal distributions and for all dimensions of xx and yy. In addition, we give estimators for redundancies between more than 2 random variables. We compare our algorithms in detail with existing algorithms. Finally, we demonstrate the usefulness of our estimators for assessing the actual independence of components obtained from independent component analysis (ICA), for improving ICA, and for estimating the reliability of blind source separation.

Keywords

Cite

@article{arxiv.cond-mat/0305641,
  title  = {Estimating Mutual Information},
  author = {Alexander Kraskov and Harald Stoegbauer and Peter Grassberger},
  journal= {arXiv preprint arXiv:cond-mat/0305641},
  year   = {2009}
}

Comments

16 pages, including 18 figures