A somewhat surprising request on X validated about the inverse cdf representation of a wrapped Cauchy distribution. I had not come across this distribution, but its density being
means that it is the superposition of shifted Cauchys on the unit circle (with nice complex representations). As such, it is easily simulated by re-shifting a Cauchy back to (-π,π), i.e. using the inverse transform
A question that came out on X validated a few days ago is how to efficiently simulate from a distribution with density
x²φ(x).
(Obviously this density is already properly normalised since the second moment of the standard Normal distribution is one.) The first solution that came out (by Jarle Tufto) exploits the fact that this density corresponds to a signed root of a χ²(3) variate. This is a very efficient proposal that requires a Gamma sampler and a random sign sampler. Since the cdf is available in closed form,
Φ(x)-xφ(x),
I ran a comparison with a numerical inversion, but this is much slower. I also tried an accept-reject version based on a Normal proposal with a larger variance, but even when optimising this variance, the running time was about twice as large. While checking Devroye (1986) for any possible if unlikely trick, I came upon this distribution twice (p.119 in an unsolved exercise, p.176 presented as the Maxwell distribution). With the remark that, if
X~x²φ(x), then Y=UX~φ(x).
Inverting this result leads to X being distributed as
sign(Y)√(Y²-2log(U)),
which recovers the original χ²(3) solution, if slightly (and mysteriously) increasing the simulation speed.
Following (as usual) an X validated question, I came across two papers of George Marsaglia on the ratio of two arbitrary (i.e. unnormalised and possibly correlated) Normal variates. One was a 1965 JASA paper,
where the density of the ratio X/Y is exhibited, based on the fact that this random variable can always be represented as (a+ε)/(b+ξ) where ε,ξ are iid N(0,1) and a,b are constant. Surprisingly (?), this representation was challenged in a 1969 paper by David Hinkley (corrected in 1970).
And less surprisingly the ratio distribution behaves almost like a Cauchy, since its density is
meaning it is a two-component mixture of a Cauchy distribution, with weight exp(-a²/2-b²/2), and of an altogether more complex distribution ƒ². This is remarked by Marsaglia in the second 2006 paper, although the description of the second component remains vague, besides a possible bimodality. (It could have a mean, actually.) The density ƒ² however resembles (at least graphically) the generalised Normal inverse density I played with, eons ago.
When solving a rather simple probability question on X validated, namely the joint uniformity of the pair
when A,B,C are iid U(0,1), I chose a rather pedestrian way and derived the joint distribution of (A-B,C-B), which turns to be made of 8 components over the (-1,1)² domain. And to conclude at the uniformity of the above, I added a hand-made picture to explain why the coverage by (X,Y) of any (red) square within (0,1)² was uniform by virtue of the symmetry between the coverage by (A-B,C-B) of four copies of the (red) square, using color tabs that were sitting on my desk..! It did not seem to convince the originator of the question, who kept answering with more questions—or worse an ever-changing question, reproduced in real time on math.stackexchange!, revealing there that said originator was tutoring an undergrad student!—but this was a light moment in a dreary final day before a new lockdown.
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