## How to generate a random point within a circle of radius *R*:

```
r = R * sqrt(random())
theta = random() * 2 * PI
```

(Assuming `random()`

gives a value between 0 and 1 uniformly)

If you want to convert this to Cartesian coordinates, you can do

```
x = r * cos(theta)
y = r * sin(theta)
```

## Why `sqrt(random())`

?

Let's look at the math that leads up to `sqrt(random())`

. Assume for simplicity that we're working with the unit circle, i.e. *R* = 1.

The average distance between points should be the same regardless of how far from the center we look. This means for example, that looking on the perimeter of a circle with circumference 2 we should find twice as many points as the number of points on the perimeter of a circle with circumference 1.

Since the circumference of a circle (2π*r*) grows linearly with *r*, it follows that the number of random points should grow linearly with *r*. In other words, the desired probability density function (PDF) grows linearly. Since a PDF should have an area equal to 1 and the maximum radius is 1, we have

So we know how the desired density of our random values should look like.
Now: **How do we generate such a random value when all we have is a uniform random value between 0 and 1?**

We use a trick called inverse transform sampling

- From the PDF, create the cumulative distribution function (CDF)
- Mirror this along
*y* = *x*
- Apply the resulting function to a uniform value between 0 and 1.

Sounds complicated? Let me insert a yellow box with a little sidetrack that conveys the intuition:

Suppose we want to generate a random point with the following distribution:

That is

- 1/5 of the points uniformly between 1 and 2, and
- 4/5 of the points uniformly between 2 and 3.

The CDF is, as the name suggests, the cumulative version of the PDF. Intuitively: While PDF(*x*) describes the number of random values *at x*, CDF(*x*) describes the number of random values *less than x*.

In this case the CDF would look like:

To see how this is useful, imagine that we shoot bullets from left to right at uniformly distributed heights. As the bullets hit the line, they drop down to the ground:

See how the density of the bullets on the ground correspond to our desired distribution! We're almost there!

The problem is that for this function, the *y* axis is the *output* and the *x* axis is the *input*. We can only "shoot bullets from the ground straight up"! We need the inverse function!

This is why we mirror the whole thing; *x* becomes *y* and *y* becomes *x*:

We call this *CDF*^{-1}. To get values according to the desired distribution, we use CDF^{-1}(random()).

…so, back to generating random radius values where our PDF equals 2*x*.

**Step 1: Create the CDF:**

Since we're working with reals, the CDF is expressed as the integral of the PDF.

*CDF*(*x*) = ∫ 2*x* = *x*^{2}

**Step 2: Mirror the CDF along ***y* = *x*:

Mathematically this boils down to swapping *x* and *y* and solving for *y*:

*CDF*: *y* = *x*^{2}

Swap: *x* = *y*^{2}

Solve: *y* = √*x*

*CDF*^{-1}: *y* = √*x*

**Step 3: Apply the resulting function to a uniform value between 0 and 1**

*CDF*^{-1}(random()) = √random()

Which is what we set out to derive :-)