A few approaches that come to mind.

### dplyr

For quick work, a dplyr approach, which has the handy `lag()`

and `lead()`

functions. First makes calculations for each row, then subsets to every other row, then pulls the calculated column.

```
library(dplyr)
test %>%
mutate(diff = (price - lead(price))^2) %>%
slice(seq(1, nrow(.), 2)) %>%
pull(diff)
```

```
[1] 25 4 81
```

### base R

A base R approach, with fun recycled logical subsetting. This one is very clearly a vectorized operation, so naturally is the fastest.

```
(test$price[c(TRUE, FALSE)] - test$price[c(FALSE, TRUE)])^2
```

```
[1] 25 4 81
```

### for loop

An inefficient-but-it-works approach:

```
inds <- seq(1, nrow(test), 2)
diff <- numeric(length(inds))
for (i in seq_along(inds)) {
diff[i] <- (test$price[inds[i]] - test$price[inds[i] + 1])^2
}
diff
```

```
[1] 25 4 81
```

### Benchmarks

```
library(microbenchmark)
test_big <- data.frame(price = rnorm(100000, mean(test$price)))
res <- microbenchmark(
dplyr = {
diff1 <- test_big %>%
mutate(diff = (price - lead(price))^2) %>%
slice(seq(1, nrow(.), 2)) %>%
pull(diff)
},
base = {
diff2 <- (test_big$price[c(TRUE, FALSE)] - test_big$price[c(FALSE, TRUE)])^2
},
loop = {
inds <- seq(1, nrow(test_big), 2)
diff3 <- numeric(length(inds))
for (i in seq_along(inds)) {
diff3[i] <- (test_big$price[inds[i]] - test_big$price[inds[i] + 1])^2
}
}
)
all(c(identical(diff1, diff2), identical(diff2, diff3)))
print(res)
```

```
[1] TRUE
Unit: microseconds
expr min lq mean median uq max neval
dplyr 1864.352 2118.08 2338.2370 2274.1060 2443.4360 3628.295 100
base 314.306 346.04 372.9717 374.7605 391.6115 495.895 100
loop 33623.116 34868.37 35641.7231 35273.2225 35975.5525 58852.630 100
```

```
ggplot2::autoplot(res)
```