For the sake of interest, it's pretty straightforward to generate normally distributed random numbers from a uniform RNG (though it must be done in pairs):

```
Random rng = new Random();
double r = Math.Sqrt(-2 * Math.Log(rng.NextDouble()));
double θ = 2 * Math.Pi * rng.NextDouble();
double x = r * Math.Cos(θ);
double y = r * Math.Sin(θ);
```

`x`

and `y`

now contain two independent, normally distributed random numbers with mean 0 and variance 1. You can scale and translate them as necessary to get the range you want (as interjay explains).

**Explanation:**

This method is called the Box–Muller transform. It uses the property of the two-dimensional unit Gaussian that the density value itself, `p = exp(-r^2/2)`

, is uniformly distributed between `0`

and `1`

(normalisation constant removed for simplicity).

Since you can generate such a value easily using a uniform RNG, you end up with a circular contour of radius `r = sqrt(-2 * log(p))`

. You can then generate a second uniform random variate between `0`

and `2*pi`

to give you an angle `θ`

that defines a unique point on your circular contour. Finally, you can generate two i.i.d. normal random variates by transforming from polar coordinates `(r, θ)`

back into cartesian coordinates `(x, y)`

.

This property – that `p`

is uniformly distributed – doesn't hold for other dimensionalities, which is why you have to generate exactly two normal variates at a time.