Let $z = xy$ be a product of two uniform random variables, with $x$ having the range $[a, b)$ and $y$ the range $[c, d)$.
What is the probability density function of $z$, and how is it calculated?
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asked Apr 29, 2013 at 6:58
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2 Answers
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There are different solutions depending on whether $a > 0$ or $a < 0$, $c > 0$ or $c < 0$ etc. If you can tie it down a bit more, I'd be happy to compute a special case for you.
In the case of: $a > 0$ and $c > 0$, there are three special sub-cases:
Case 1: $a d > b c$
Case 2: $a d < b c$
Case 3: $a d = b c$
Here is the output for Case 1 using the mathStatica/Mathematica combo ...
Case 1: $a > 0$, $c > 0$, $a d > b c$
Given $X \sim \text{Uniform}(a,b)$ with pdf $f(x)$, and $Y \sim \text{Uniform}(c,d)$ with pdf $g(y)$ and parameters $a>0$ and $c>0$, we have:
f = 1/(b-a); domain[f] = {x, a, b} && {0 < a < b, a d > b c};
g = 1/(d-c); domain[g] = {y, c, d} && {0 < c < d};
Find pdf of the product $Z = X * Y$, say $h(z)$:
h = TransformProduct[{f, g}, z]
with domain of support (just define it on the real line):
domain[h] = {z, -∞, ∞};
Here is a plot of the pdf for Case 1:
PlotDensity[h /. {a -> 2, b -> 4, c -> 1/2, d -> {6, 7, 8}}]
update ...
Case 3: $a > 0$, $c > 0$, $a d == b c$
Case 3 is really just a special case of case 1 ...
Given $X \sim \text{Uniform}(a,b)$ with pdf $f(x)$, and $Y \sim \text{Uniform}(c,d)$ with pdf $g(y)$, and parameters $a>0$ and $c>0$, we have:
f = 1/(b-a); domain[f] = {x, a, b} && {0 < a < b, a d == b c};
g = 1/(d-c); domain[g] = {y, c, d} && {0 < c < d};
Find pdf of the product $Z = X * Y$, say $h(z)$:
h = TransformProduct[{f, g}, z]
with domain of support (just define it on the real line):
domain[h] = {z, -∞, ∞};
Here is a plot of the pdf for Case 3, for your set-up, with $a = c$, and $b = d$:
PlotDensity[h /. {a -> Range[5], b -> 12, c -> Range[5], d -> 12}]
... and you are all done :) I might update the mathStatica code to automatically output all the special cases ... for the next version :)
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$\begingroup$ In case 2, of course, we can simply make a change of variables and use case one, as they're symmetric. At the moment, I have two specific cases, both with a>0, c>0, one of which falls into case 1, but the other falls into case 3, as a=c, b=d. I'd also really like to have the probability density function Pz(a,b,c,d) if possible, as I don't have access to Mathematica, and there are a lot of different ranges of z that are significant for this problem, more than I could ask someone to solve for me. $\endgroup$ Commented Apr 29, 2013 at 14:54
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$\begingroup$ @TheodoreMurdock Hi Theo - yes, case 2 by symmetry, and case 3 can be obtained as a special case of case 1 or 2. I've updated the above to include case 3 + plot. $\endgroup$– wolfiesCommented Apr 29, 2013 at 15:39
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$\begingroup$ Oh...sorry for being slow to get it, I just realized your function h is the probability density I need, taking different forms in different regions of the graph. Thanks for the help! Now I just need to plug in the numbers, integrate over the proper interval, and I'll be able to clear up the confusion I started a few years ago over how many dwarves are fat enough and tall enough to wield a two-handed sword in dwarf fortress. $\endgroup$ Commented Apr 29, 2013 at 15:52
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$\begingroup$ In an example to a recent answer, I computed the density of the product of two uniform variables on $[0,1]$. I am pleased to see that my result is confirmed here. (+1) $\endgroup$– robjohn ♦Commented Mar 28, 2014 at 10:39
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The general formula for the pdf of the product $Z=XY$ of two random variables $X$ and $Y$ is given by
$$p_{Z}(z)= \int_{-\infty}^{\infty}\frac{1}{|x|}p_{XY}\left (x,\frac{z}{x}\right )\;dx$$
where $p_{XY}(x,y)$ is the joint distribution of the two random variables. If they are independent you can use $p_{XY}(x,y)=p_X(x)p_Y(y)$.
