Since the integral is the cumulative PDF of a normal distribution (except for the missing normalization factor) you can calculate it with `pnorm`

.

```
sf <- 1
mf <- 0
f <- function(x) 1/(2*sf^2*pi)*exp(-.5*((x-mf)/sf)^2) *
(1 - sf*sqrt(2*pi)*pnorm(x, mf, sf))
curve(f, from=-2, to=2)
```

The `sf*sqrt(2*pi)`

factor is to compensate for the missing normalization. I am not 100% sure I got the mathematics correct though, so please verify it yourself too.

**Edit:** As Ben Bolker pointed out the first part of `f`

can be simplified with `dnorm`

, making the code more readable.

```
f <- function(x) dnorm(x, mf, sf)/(sqrt(2*pi)*sf) *
(1 - sf*sqrt(2*pi)*pnorm(x, mf, sf))
```