If you want a linear drop-off what you're describing is called a triangle (or triangular) distribution. Given `U`

, a source of uniformly distributed random numbers on the range `[0,1)`

, you can generate a triangle on the range `[a,b)`

with its mode at `a`

using:

```
def triangle(a,b)
return a + (b-a)*(1 - sqrt(U))
end
```

This can be derived by writing the equation of a triangle for the specified range, scaling it so it has area 1 to make it a valid density, integrating to get the CDF, and using inversion.

As an interesting aside, this will still work if `a >= b`

. For equality, you always get `a`

(which makes sense if the range is zero). Otherwise, you get a triangle which goes from `b`

to `a`

and has its mode at `a`

.

`R`

, you can draw a sample from, say, a lognormal distribution with`rlnorm(n, meanlog = 0, sdlog = 1)`

. – ako Jul 12 '14 at 15:30