In R, linear least squares models are fitted via the `lm()`

function. Using the formula interface we can use the `subset`

argument to select the data points used to fit the actual model, for example:

```
lin <- data.frame(x = c(0:6), y = c(0.3, 0.1, 0.9, 3.1, 5, 4.9, 6.2))
linm <- lm(y ~ x, data = lin, subset = 2:4)
```

giving:

```
R> linm
Call:
lm(formula = y ~ x, data = lin, subset = 2:4)
Coefficients:
(Intercept) x
-1.633 1.500
R> fitted(linm)
2 3 4
-0.1333333 1.3666667 2.8666667
```

As for the double log, you have two choices I guess; i) estimate two separate models as we did above, or ii) estimate via ANCOVA. The log transformation is done in the formula using `log()`

.

Via two separate models:

```
logm1 <- lm(log(y) ~ log(x), data = dat, subset = 1:7)
logm2 <- lm(log(y) ~ log(x), data = dat, subset = 8:15)
```

Or via ANCOVA, where we need an indicator variable

```
dat <- transform(dat, ind = factor(1:15 <= 7))
logm3 <- lm(log(y) ~ log(x) * ind, data = dat)
```

You might ask if these two approaches are equivalent? Well they are and we can show this via the model coefficients.

```
R> coef(logm1)
(Intercept) log(x)
-0.0001487042 -0.4305802355
R> coef(logm2)
(Intercept) log(x)
0.1428293 -1.4966954
```

So the two slopes are -0.4306 and -1.4967 for the separate models. The coefficients for the ANCOVA model are:

```
R> coef(logm3)
(Intercept) log(x) indTRUE log(x):indTRUE
0.1428293 -1.4966954 -0.1429780 1.0661152
```

How do we reconcile the two? Well the way I set up `ind`

, `logm3`

is parametrised to give more directly values estimated from `logm2`

; the intercepts of `logm2`

and `logm3`

are the same, as are the coefficients for `log(x)`

. To get the values equivalent to the coefficients
of `logm1`

, we need to do a manipulation, first for the intercept:

```
R> coefs[1] + coefs[3]
(Intercept)
-0.0001487042
```

where the coefficient for `indTRUE`

is the difference in the mean of group 1 over the mean of group 2. And for the slope:

```
R> coefs[2] + coefs[4]
log(x)
-0.4305802
```

which is the same as we got for `logm1`

and is based on the slope for group 2 (`coefs[2]`

) modified by the difference in slope for group 1 (`coefs[4]`

).

As for plotting, an easy way is via `abline()`

for simple models. E.g. for the normal data example:

```
plot(y ~ x, data = lin)
abline(linm)
```

For the log data we might need to be a bit more creative, and the general solution here is to predict over the range of data and plot the predictions:

```
pdat <- with(dat, data.frame(x = seq(from = head(x, 1), to = tail(x,1),
by = 0.1))
pdat <- transform(pdat, yhat = c(predict(logm1, pdat[1:70,, drop = FALSE]),
predict(logm2, pdat[71:141,, drop = FALSE])))
```

Which can plot on the original scale, by exponentiating `yhat`

```
plot(y ~ x, data = dat)
lines(exp(yhat) ~ x, dat = pdat, subset = 1:70, col = "red")
lines(exp(yhat) ~ x, dat = pdat, subset = 71:141, col = "blue")
```

or on the log scale:

```
plot(log(y) ~ log(x), data = dat)
lines(yhat ~ log(x), dat = pdat, subset = 1:70, col = "red")
lines(yhat ~ log(x), dat = pdat, subset = 71:141, col = "blue")
```

For example...

This general solution works well for the more complex ANCOVA model too. Here I create a new pdat as before and add in an indicator

```
pdat <- with(dat, data.frame(x = seq(from = head(x, 1), to = tail(x,1),
by = 0.1)[1:140],
ind = factor(rep(c(TRUE, FALSE), each = 70))))
pdat <- transform(pdat, yhat = predict(logm3, pdat))
```

Notice how we get all the predictions we want from the single call to `predict()`

because of the use of ANCOVA to fit `logm3`

. We can now plot as before:

```
plot(y ~ x, data = dat)
lines(exp(yhat) ~ x, dat = pdat, subset = 1:70, col = "red")
lines(exp(yhat) ~ x, dat = pdat, subset = 71:141, col = "blue")
```