English

Ratios and Cauchy Distribution

Statistics Theory 2016-03-04 v2 Probability Statistics Theory

Abstract

It is well known that the ratio of two independent standard Gaussian random variables follows a Cauchy distribution. Any convex combination of independent standard Cauchy random variables also follows a Cauchy distribution. In a recent joint work, the author proved a surprising multivariate generalization of the above facts. Fix m>1m > 1 and let Σ\Sigma be a m×mm\times m positive semi-definite matrix. Let X,YN(0,Σ)X,Y \sim \mathrm{N}(0,\Sigma) be independent vectors. Let w=(w1,,wm)\vec{w}=(w_1, \dots, w_m) be a vector of non-negative numbers with j=1mwj=1.\sum_{j=1}^m w_j = 1. The author proved recently that the random variable Z=j=1mwjXjYj   Z = \sum_{j=1}^m w_j\frac{X_j}{Y_j}\; also has the standard Cauchy distribution. In this note, we provide some more understanding of this result and give a number of natural generalizations. In particular, we observe that if (X,Y)(X,Y) have the same marginal distribution, they need neither be independent nor be jointly normal for ZZ to be Cauchy distributed. In fact, our calculations suggest that joint normality of (X,Y)(X,Y) may be the only instance in which they can be independent. Our results also give a method to construct copulas of Cauchy distributions.

Keywords

Cite

@article{arxiv.1602.08181,
  title  = {Ratios and Cauchy Distribution},
  author = {Natesh S. Pillai},
  journal= {arXiv preprint arXiv:1602.08181},
  year   = {2016}
}

Comments

Generalization of a recent conjecture on Cauchy distribution; added a Remark and updated references

R2 v1 2026-06-22T12:58:17.788Z