For any model fitting, I would do the fitting outside of the plotting paradigm I was using. For this, pass a value to `weights`

that is inversely proportional to the variances of the observations. Fitting will then be done via a weighted least squares procedure.

For your example/situation **ggplot**'s `geom_smooth`

is doing the following for you. Whist it may seem easier to use `geom_Smooth`

, the benefits of fitting the model directly eventually outweigh this. For one, you have the fitted model and can perform diagnostics on the fit, assumptions of the model etc.

Fit the weighted least squares

```
mod <- lm(y ~ x, data = dat, weights = 1/sqrt(yerr))
```

Then `predict()`

from the model over the range of `x`

```
newx <- with(dat, data.frame(x = seq(min(x), max(x), length = 50)))
pred <- predict(mod, newx, interval = "confidence", level = 0.95)
```

In the above we get the `predict.lm`

method to generate the appropriate confidence interval for use.

Next, prepare the data for plotting

```
pdat <- with(data.frame(pred),
data.frame(x = newx, y = fit, ymax = upr, ymin = lwr))
```

Next, build the plot

```
require(ggplot2)
p <- ggplot(dat, aes(x = x, y = y)) +
geom_point() +
geom_line(data = pdat, colour = "blue") +
geom_ribbon(mapping = aes(ymax = ymax, ymin = ymin), data = pdat,
alpha = 0.4, fill = "grey60")
p
```

otherthan physics, in which things are done differently. Doing experiments with physical instruments with none error rates is something you do regularly, but it's something that, say, a wildlife biologist would find pretty foreign. To them, the idea that you haveknownmeasurement errors on your y variables would be pretty weird. – joran Feb 1 '13 at 13:55common(and I have a PhD in statistics!). – joran Feb 1 '13 at 13:57