When specifying `interval`

and `level`

argument, `predict.lm`

can return confidence interval (CI) or prediction interval (PI). This answer shows how to obtain CI and PI without setting these arguments. There are two ways:

- use middle-stage result from
`predict.lm`

;
- do everything from scratch.

Knowing how to work with both ways give you a thorough understand of the prediction procedure.

Note that we will only cover the `type = "response"`

(default) case for `predict.lm`

. Discussion of `type = "terms"`

is beyond the scope of this answer.

## Setup

I gather your code here to help other readers to copy, paste and run. I also change variable names so that they have clearer meanings. In addition, I expand the `newdat`

to include more than one rows, to show that our computations are "vectorized".

```
dat <- structure(list(V1 = c(20L, 60L, 46L, 41L, 12L, 137L, 68L, 89L,
4L, 32L, 144L, 156L, 93L, 36L, 72L, 100L, 105L, 131L, 127L, 57L,
66L, 101L, 109L, 74L, 134L, 112L, 18L, 73L, 111L, 96L, 123L,
90L, 20L, 28L, 3L, 57L, 86L, 132L, 112L, 27L, 131L, 34L, 27L,
61L, 77L), V2 = c(2L, 4L, 3L, 2L, 1L, 10L, 5L, 5L, 1L, 2L, 9L,
10L, 6L, 3L, 4L, 8L, 7L, 8L, 10L, 4L, 5L, 7L, 7L, 5L, 9L, 7L,
2L, 5L, 7L, 6L, 8L, 5L, 2L, 2L, 1L, 4L, 5L, 9L, 7L, 1L, 9L, 2L,
2L, 4L, 5L)), .Names = c("V1", "V2"),
class = "data.frame", row.names = c(NA, -45L))
lmObject <- lm(V1 ~ V2, data = dat)
newdat <- data.frame(V2 = c(6, 7))
```

The following are the output of `predict.lm`

, to be compared with our manual computations later.

```
predict(lmObject, newdat, se.fit = TRUE, interval = "confidence", level = 0.90)
#$fit
# fit lwr upr
#1 89.63133 87.28387 91.9788
#2 104.66658 101.95686 107.3763
#
#$se.fit
# 1 2
#1.396411 1.611900
#
#$df
#[1] 43
#
#$residual.scale
#[1] 8.913508
predict(lmObject, newdat, se.fit = TRUE, interval = "prediction", level = 0.90)
#$fit
# fit lwr upr
#1 89.63133 74.46433 104.7983
#2 104.66658 89.43930 119.8939
#
#$se.fit
# 1 2
#1.396411 1.611900
#
#$df
#[1] 43
#
#$residual.scale
#[1] 8.913508
```

## Use middle-stage result from `predict.lm`

```
## use `se.fit = TRUE`
z <- predict(lmObject, newdat, se.fit = TRUE)
#$fit
# 1 2
# 89.63133 104.66658
#
#$se.fit
# 1 2
#1.396411 1.611900
#
#$df
#[1] 43
#
#$residual.scale
#[1] 8.913508
```

What is `se.fit`

?

`z$se.fit`

is the standard error of the predicted mean `z$fit`

, used to construct CI for `z$fit`

. We also need quantiles of t-distribution with a degree of freedom `z$df`

.

```
alpha <- 0.90 ## 90%
Qt <- c(-1, 1) * qt((1 - alpha) / 2, z$df, lower.tail = FALSE)
#[1] -1.681071 1.681071
## 90% confidence interval
CI <- z$fit + outer(z$se.fit, Qt)
colnames(CI) <- c("lwr", "upr")
CI
# lwr upr
#1 87.28387 91.9788
#2 101.95686 107.3763
```

We see that this agrees with `predict.lm(, interval = "confidence")`

.

What is the standard error for PI?

PI is wider than CI, as it accounts for residual variance:

```
variance_of_PI = variance_of_CI + variance_of_residual
```

Note that this is defined point-wise. For a non-weighted linear regression (as in your example), residual variance is equal everywhere (known as *homoscedasticity*), and it is `z$residual.scale ^ 2`

. Thus the standard error for PI is

```
se.PI <- sqrt(z$se.fit ^ 2 + z$residual.scale ^ 2)
# 1 2
#9.022228 9.058082
```

and PI is constructed as

```
PI <- z$fit + outer(se.PI, Qt)
colnames(PI) <- c("lwr", "upr")
PI
# lwr upr
#1 74.46433 104.7983
#2 89.43930 119.8939
```

We see that this agrees with `predict.lm(, interval = "prediction")`

.

**remark**

Things are more complicated if you have a weight linear regression, where the residual variance is not equal everywhere so that `z$residual.scale ^ 2`

should be weighted. It is easier to construct PI for fitted values (that is, you don't set `newdata`

when using `type = "prediction"`

in `predict.lm`

), because the weights are known (you must have provided it via `weight`

argument when using `lm`

). For out-of-sample prediction (that is, you pass a `newdata`

to `predict.lm`

), `predict.lm`

expects you to tell it how residual variance should be weighted. You need either use argument `pred.var`

or `weights`

in `predict.lm`

, otherwise you get a warning from `predict.lm`

complaining insufficient information for constructing PI. The following are quoted from `?predict.lm`

:

```
The prediction intervals are for a single observation at each case
in ‘newdata’ (or by default, the data used for the fit) with error
variance(s) ‘pred.var’. This can be a multiple of ‘res.var’, the
estimated value of sigma^2: the default is to assume that future
observations have the same error variance as those used for
fitting. If ‘weights’ is supplied, the inverse of this is used as
a scale factor. For a weighted fit, if the prediction is for the
original data frame, ‘weights’ defaults to the weights used for
the model fit, with a warning since it might not be the intended
result. If the fit was weighted and ‘newdata’ is given, the
default is to assume constant prediction variance, with a warning.
```

Note that construction of CI is not affected by the type of regression.

## Do everything from scratch

Basically we want to know how to obtain `fit`

, `se.fit`

, `df`

and `residual.scale`

in `z`

.

The predicted mean can be computed by a matrix-vector multiplication `Xp %*% b`

, where `Xp`

is the linear predictor matrix and `b`

is regression coefficient vector.

```
Xp <- model.matrix(delete.response(terms(lmObject)), newdat)
b <- coef(lmObject)
yh <- c(Xp %*% b) ## c() reshape the single-column matrix to a vector
#[1] 89.63133 104.66658
```

And we see that this agrees with `z$fit`

. The variance-covariance for `yh`

is `Xp %*% V %*% t(Xp)`

, where `V`

is the variance-covariance matrix of `b`

which can be computed by

```
V <- vcov(lmObject) ## use `vcov` function in R
# (Intercept) V2
# (Intercept) 7.862086 -1.1927966
# V2 -1.192797 0.2333733
```

The full variance-covariance matrix of `yh`

is not needed to compute point-wise CI or PI. We only need its main diagonal. So instead of doing `diag(Xp %*% V %*% t(Xp))`

, we can do it more efficiently via

```
var.fit <- rowSums((Xp %*% V) * Xp) ## point-wise variance for predicted mean
# 1 2
#1.949963 2.598222
sqrt(var.fit) ## this agrees with `z$se.fit`
# 1 2
#1.396411 1.611900
```

The residual degree of freedom is readily available in the fitted model:

```
dof <- df.residual(lmObject)
#[1] 43
```

Finally, to compute residual variance, use Pearson estimator:

```
sig2 <- c(crossprod(lmObject$residuals)) / dof
# [1] 79.45063
sqrt(sig2) ## this agrees with `z$residual.scale`
#[1] 8.913508
```

**remark**

Note that in case of weighted regression, `sig2`

should be computed as

```
sig2 <- c(crossprod(sqrt(lmObject$weights) * lmObject$residuals)) / dof
```

## Appendix: a self-written function that mimics `predict.lm`

The code in "Do everything from scratch" has been cleanly organized into a function `lm_predict`

in this Q & A: linear model with `lm`

: how to get prediction variance of sum of predicted values.

`?predict.lm`

, it says:". "Predicted means" makes it sounds like it applies only to the confidence interval. If you don't want to see it, set`se.fit`

: standard error of predicted means"`se.fit = FALSE`

. – Gregor Jun 29 '16 at 20:50