Given a function
random() which returns floating-point value uniformly distributed between 0 and 1.
What's the type of distribution of function
random() * random()?
# test.py import numpy as np import matplotlib.pyplot as plt N = 10**6 plt.hist(np.random.uniform(size=N) * np.random.uniform(size=N), bins=50, normed=True) plt.show()
python test.py produces:
The type is a Product Distribution, it is not uniform anymore.
The transformation is y = x*x. x has the probability distribution function fx(x) = 1 on the range 0 <=x <= 1. The cumulative distribution function of x is then Fx(x) = x on the same range.
The CDF of y is Fy(y <= Y) = Fx(sqrt(Y)) = sqrt(Y), 0 <= Y <= 1.
Now differentiate to get fy(y) = 1/(2*sqrt(y)) on the same range.
The above solution assumes that "random() * random()" uses the same value dependently for each draw. If instead you want the multiplied values to be independent of one another, the math is more involved but still tractable.
y1 = x1*x2 where fx1(x1) = 1 on 0 <= x1 <= 1 and similarly for x2.
Assuming independence between x1 and x2, the joint PDF is
fx1x2(x1,x2) = fx1(x1)*fx2(x2).
Introduce an additional variable y2 to deal with the transformation of 2-variable joint PDFs. For nice calculations, let y2 = x2.
So our system is
g1(x1,x2) = x1*x2
g2(x1,x2) = x2
As in the simpler case, we need to invert the function, now by solving for both y1 and y2:
h2(y1,y2) = x2 (= y2)
h1(y1,y2) = y1/x2 = y1/y2
We will need the Jacobian
J = (pg1/px1)(pg2/px2) - (pg1/px2)(pg2/x1)
where "p" is partial derivative.
So in our case
J = (x2)(1) - (x1)(0) = x2.
The transformation formula (from any intro calculus-based probability text) is
fy1y2(y1,y2) = fx1x2(x1,x2)/J
which in our case simplifies to
1/y2 on the range 0 <= y1/y2 <= 1 and 0 <= y2 <= 1.
Finally, to get fy1(y1) we integrate the joint distribution over the unwanted variable y2, taking care to stay in the correct range y1/y2 <= 1 or y1 <= y2 since y2 >= 0.
fy1(y1) = Integral from y1 to 1 of (1/y2)dy2 = -ln(y1) on the range 0 <= y1 <= 1.
Note that in both cases, the distribution of the product is weighted in favor of smaller values, since a fraction (0 <= x <= 1) times a fraction is a smaller fraction.