# Probability Density Function

How would I simulate a probability density function in MATLAB such that

``````fx(x)={ x/8    0<=x<=4
{   0     Other
``````

Thanks!

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Simulation from an arbitrary probability density function is done as follows:

1) Derive the inverse cumulative distribution.

2) Simulate from a uniform [0, 1] distribution.

3) Plug the uniform [0, 1] numbers into the inverse cumulative distribution.

In your situation, you have a nice easy probability density to work with, leading me to suspect that this is a homework question. Given that you haven't posted any code indicating that you've attempted to solve it yourself, I'm not going to just write out the answer for you.

Instead, why don't you have a go at deriving the inverse cumulative distribution yourself? First you'll need to get the cumulative distribution. This can be done by finding the integral of your probability density from minus infinity to x, which in your case is equivalent to the integral from 0 to x. Once you've done this, you need to find the inverse of it. The example here should be sufficient to show you how to do that for your simple case. If you get that far, then use `rand(100, 1)` to simulate 100 draws from the uniform [0, 1] density, and then plug those numbers into your inverse cumulative distribution.

Cheers.

UPDATE: I figure the OP's homework was probably due by now, so for completeness: The integral of the probability density, ie the cumulative distribution, is f(x) = (1/16) x^2. Note that when x = 0, f(x) = 0, and when x = 4, f(x) = 1. This demonstrates that the question has stated the domain of the probability density correctly. Next, f(x) implies an inverse CDF of g(x) = 4 * x^(1/2). Hence:

``````MyInverseCDF = @(x) (4 * sqrt(x));
MySimulatedDraw = MyInverseCDF(rand(100, 1));
``````

We can visually validate that everything is working using:

``````hist(MySimulatedDraw);
``````

One other thing, here is a link to another related SO question: defining-your-own-probability-distribution-function-in-matlab

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+1 for being so diplomatic! The way things should be. – Adam27X Dec 4 '12 at 4:22
Thanks Colin. You were right this problem does come from homework. We were suppose to do this by using symbolic integration. I just wanted to simulate this seeing how the probabilities differed with different densities. – Joe Dec 4 '12 at 14:52
@Joe Did you solve it? As I said, in my answer, if you run into problems, post them here and I am happy to help. – Colin T Bowers Dec 4 '12 at 22:42