If you *really* want to do this (remove the largest (absolute) residuals), then we can employ the linear model to estimate the least squares solution and associated residuals and then select the middle n% of the data. Here is an example:

Firstly, generate some dummy data:

```
require(MASS) ## for mvrnorm()
set.seed(1)
dat <- mvrnorm(1000, mu = c(4,5), Sigma = matrix(c(1,0.8,1,0.8), ncol = 2))
dat <- data.frame(dat)
names(dat) <- c("X","Y")
plot(dat)
```

Next, we fit the linear model and extract the residuals:

```
res <- resid(mod <- lm(Y ~ X, data = dat))
```

The `quantile()`

function can give us the required quantiles of the residuals. You suggested retaining 90% of the data, so we want the upper and lower 0.05 quantiles:

```
res.qt <- quantile(res, probs = c(0.05,0.95))
```

Select those observations with residuals in the middle 90% of the data:

```
want <- which(res >= res.qt[1] & res <= res.qt[2])
```

We can then visualise this, with the red points being those we will retain:

```
plot(dat, type = "n")
points(dat[-want,], col = "black", pch = 21, bg = "black", cex = 0.8)
points(dat[want,], col = "red", pch = 21, bg = "red", cex = 0.8)
abline(mod, col = "blue", lwd = 2)
```

The correlations for the full data and the selected subset are:

```
> cor(dat)
X Y
X 1.0000000 0.8935235
Y 0.8935235 1.0000000
> cor(dat[want,])
X Y
X 1.0000000 0.9272109
Y 0.9272109 1.0000000
> cor(dat[-want,])
X Y
X 1.000000 0.739972
Y 0.739972 1.000000
```

Be aware that here we might be throwing out perfectly good data, because we just choose the 5% with largest positive residuals and 5% with the largest negative. An alternative is to select the 90% with smallest *absolute* residuals:

```
ares <- abs(res)
absres.qt <- quantile(ares, prob = c(.9))
abswant <- which(ares <= absres.qt)
## plot - virtually the same, but not quite
plot(dat, type = "n")
points(dat[-abswant,], col = "black", pch = 21, bg = "black", cex = 0.8)
points(dat[abswant,], col = "red", pch = 21, bg = "red", cex = 0.8)
abline(mod, col = "blue", lwd = 2)
```

With this slightly different subset, the correlation is slightly lower:

```
> cor(dat[abswant,])
X Y
X 1.0000000 0.9272032
Y 0.9272032 1.0000000
```

Another point is that even then we are throwing out good data. You might want to look at Cook's distance as a measure of the strength of the outliers, and discard only those values above a certain threshold Cook's distance. Wikipedia has info on Cook's distance and proposed thresholds. The `cooks.distance()`

function can be used to retrieve the values from `mod`

:

```
> head(cooks.distance(mod))
1 2 3 4 5 6
7.738789e-04 6.056810e-04 6.375505e-04 4.338566e-04 1.163721e-05 1.740565e-03
```

and if you compute the threshold(s) suggested on Wikipedia and remove only those that exceed the threshold. For these data:

```
> any(cooks.distance(mod) > 1)
[1] FALSE
> any(cooks.distance(mod) > (4 * nrow(dat)))
[1] FALSE
```

none of the Cook's distances exceed the proposed thresholds (not surprising given the way I generated the data.)

Having said all of this, why do you want to do this? If you are just trying to get rid of data to improve a correlation or generate a significant relationship, that sounds a bit fishy and bit like data dredging to me.

`x`

and`y`

? – Gavin Simpson Jan 12 '11 at 9:13