Could anyone give me some practical examples of the Cauchy Distribution? What makes it so popular?
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5$\begingroup$ I challenge the premise -- is it actually popular as a practical model*? (If it is, how do you know, outside of seeing practical examples already?) ... $\:$ *[It's widely used in textbook examples because of its simplicity and as a counterexample to various things, but I doubt those count as practical. It's sometimes used as a prior, but that's not as a data model.] $\endgroup$– Glen_bCommented Jul 7, 2019 at 9:30
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$\begingroup$ I've seen some practical examples out of my field of studies, specifically for MCMC algorithm. Therefore I've been curious if it can be applied for finance or ML $\endgroup$– DariaCommented Jul 7, 2019 at 9:32
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$\begingroup$ When you say "for MCMC algorithm" do you mean instead "as a Bayesian prior" or do you mean "as a model for data in a Bayesian framework" or something else? $\endgroup$– Glen_bCommented Jul 7, 2019 at 9:34
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$\begingroup$ For computing hierarchical prior and reference prior. $\endgroup$– DariaCommented Jul 7, 2019 at 9:40
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2$\begingroup$ Its use as a prior is because of the distribution's properties (in general, the aim is to give some kind of weakly informative prior); from the wording of the question I wouldn't have thought you meant to include priors. There's a somewhat related question here: What are the properties of a half Cauchy distribution? $\endgroup$– Glen_bCommented Jul 7, 2019 at 9:59
2 Answers
In addition to its usefulness in physics, the Cauchy distribution is commonly used in models in finance to represent deviations in returns from the predictive model. The reason for this is that practitioners in finance are wary of using models that have light-tailed distributions (e.g., the normal distribution) on their returns, and they generally prefer to go the other way and use a distribution with very heavy tails (e.g., the Cauchy). The history of finance is littered with catastrophic predictions based on models that did not have heavy enough tails in their distributions. The Cauchy distribution has sufficiently heavy tails that its moments do not exist, and so it is an ideal candidate to give an error term with extremely heavy tails.
Note that this issue of the fatness of tails in error terms in finance models was one of the main contents of the popular critique by Taleb (2007). In that book, Taleb points out instances where financial models have used the normal distribution for error terms, and he notes that this underestimates the true probability of extreme events, which are particularly important in finance. (In my view this book gives an exaggerated critique, since models using heavy-tailed deviations are in fact quite common in finance. In any case, the popularity of this book shows the importance of the issue.)
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$\begingroup$ Thank you, I highly appreciate your answer as I am familiar with the book. By the way, I am not sure if I understand this part of your sentence correctly " fatness of tails in error terms". Would you mind being more precise with that? $\endgroup$– DariaCommented Jul 8, 2019 at 14:39
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$\begingroup$ In this kind of general discussion, we do not have a specific tail property in mind, so precision in specifying the meaning of "fatness" or "heaviness" of the tails detracts from the generality. It is worth reviewing some characterisations of fat-tailed distributions and heavy-tailed distributions to see the kind of properties I have in mind. $\endgroup$– BenCommented Jul 8, 2019 at 22:02
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$\begingroup$ Could you explain what the precision means in the plain English? I mean, I do get that it’s inverse of variance, but I seek understanding why if we talk about priors, we get n0 in the denominator - the prior sample size. $\endgroup$– DariaCommented Jul 8, 2019 at 22:41
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$\begingroup$ Without seeing the context of what you're talking about, what you ask is unclear. May I suggest that you pose this as a new question on this site, with all the relevant context given. $\endgroup$– BenCommented Jul 8, 2019 at 23:36
The standard Cauchy distribution is derived from ratio of two independent normally distributed random variables. If $X \sim N(0,1)$, and $Y \sim N(0,1)$, then $\tfrac{X}{Y} \sim \operatorname{Cauchy}(0,1)$.
The Cauchy distribution is important in physics (where it’s known as the Lorentz distribution) because it’s the solution to the differential equation describing forced resonance. In spectroscopy, it is the description of the shape of spectral lines which are subject to homogeneous broadening in which all atoms interact in the same way with the frequency range contained in the line shape.
Applications:
Used in mechanical and electrical theory, physical anthropology and measurement and calibration problems.
In physics it is called a Lorentzian distribution, where it is the distribution of the energy of an unstable state in quantum mechanics.
Also used to model the points of impact of a fixed straight line of particles emitted from a point source.
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2$\begingroup$ It's not really used in finance or machine learning (practically); it's used in physics (99.9% of the time). I suppose that if someone wanted to model the ratio between two independent, normally distributed variables in finance, they would use the Cauchy distribution. $\endgroup$ Commented Jul 6, 2019 at 20:53
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2$\begingroup$ A reason it could be useful in finance is that it has extremely heavy tails. It has no moments, so it doesn’t make sense to say that it has high kurtosis, but it is prone to extreme observations, both high and low. $\endgroup$– DaveCommented Jul 6, 2019 at 21:06
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7$\begingroup$ It is used in machine learning, in particular as a prior distribution in Bayesian inference. In particular the half-Cauchy is used as a prior for certain scale variables. $\endgroup$– WayneCommented Jul 6, 2019 at 21:42
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2$\begingroup$ @Wayne Could you please give an example, maybe a reference? $\endgroup$– DaveCommented Jul 6, 2019 at 22:21
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1$\begingroup$ "ratio of two independent normal distributions" isn't exactly right. That should say "ratio of two independent normally distributed random variables." $\endgroup$ Commented Jul 7, 2019 at 23:39