Random Variables and Signals
Topic 13: Functions of Two Random Variables
One Function of Two Random Variables
Given random variables X and Y and a function g:R$ ^2 $→R, let Z = g(X,Y). What is f$ _Z $(z)?
We assume that Z is a valid random variable, so that ∀z ∈ R, there is a D$ _z $ ∈ b(R$ ^2 $) such that
i.e.
Then,
and we can find f$ _Z $ from this.
Example $ \qquad $ g(x,y) = x + y. So Z = X + Y. Here,
and
If we now assume that X and Y are independent, then
Then,
So if X and Y are independent, and Z = X + Y, we can find f$ _Z $ by convolving f$ _X $ and f$ _Y $.
Example $ \qquad $ X and Y are independent exponential random variables with means $ \mu_X $ = $ \mu_Y $ = $ \mu $. So,
So the sum of two independent exponential random variables is not an exponential random variable.
Two Functions of Two Random Variables
Given two random variables X and Y, cobsider random variables Z and W defined as follows:
where g:R$ ^2 $→R and h:R$ ^2 $→R.
For example, if we have a linear transformation, then
where A is a 2x2 matrix. In this case,
where
How do we find f$ _{ZW} $?
If we could find D$ _{z,w} $ = {(x,y) ∈ R$ ^2 $: g(x,y) ≤ z and h(x,y) ≤ w} for every (z,w) ∈ R$ ^2 $, then we could compute
It is often quite difficult to find D$ _{z,w} $, so we use a formula for f$ _{ZW} $ instead.
Formula for Joint pdf f$ ZW $
Assume that the functions g and h satisfy
- z = g(x,y) and w = h(x,y) can be solved simultaneously for unique x and y. We will write x = g$ ^{-1} $(z,w) and y = h$ ^{-1} $(z,w) where g$ ^{-1} $:R$ ^2 $→R and h$ ^{-1} $:R$ ^2 $→R.
- For the linear transformation example, this means we assume A$ ^{-1} $ exists (i.e. it is invertible). In this case
- where
- The partial derivatives
- exist.
Then it can be shown that
where
Note that we take the absolute value of the determinant. This is called the Jacobian of the transformation. For more on the Jacobian, see here.
The proof for the above formula is in Papoulis.
Example X and Y are iid (independent and identically distributed) Gaussian random variables with $ \mu_X=\mu_Y=\mu = 0 $, $ \sigma^2 $$ _X $=$ \sigma^2 $$ _Y $=$ \sigma^2 $ and r = 0. Then, br/>
Let