@PaulHiemstra and @BenBarnes provide correct answers. I just want to add to their explanations.

**Vectors vs. arrays**

Vectors are the fundamental data structure in R. Almost everything is internally represented as a vector, even lists (with the exception of a special kind of list, the dotted pair list, see `?list`

). Arrays are simply vectors with an attribute attached, the `dim`

attribute, which describes the object's dimensions. Consider the following:

```
v <- c(1:10)
a <- array(v, dim = c(5, 2))
length(v) # 10
length(a) # 10
attributes(v) # NULL
attributes(a) # $dim 10 1
is.vector(v) # TRUE
is.array(v) # FALSE
is.vector(a) # FALSE
is.array(a) # TRUE
```

Both `v`

and `a`

are length `10`

. The only difference is `a`

has the `dim`

attribute attached to it. Because of this added attribute, R treats `a`

externally as an array instead of a vector. Modifying just the `dim`

attribute can change R's external representation of an object from array to vector and back:

```
attr(a, "dim") <- NULL
is.vector(a) # TRUE
is.array(a) # FALSE
attr(v, "dim") <- c(5, 2)
is.vector(v) # FALSE
is.array(v) # TRUE
```

In your example, `temp2`

is a vector object, thus lacking a `dim`

attribute. `colMeans`

is expecting an `array`

object with a `dim`

attribute of at least length 2 (two dimensional). You can easily convert `temp2`

to a two dimensional array with a single column:

```
temp3 <- array(temp2, dim = c(length(temp2), 1))
# or:
temp4 <- temp2
attr(temp4, "dim") <- c(length(temp2), 1)
is.array(temp2) # FALSE
is.array(temp3) # TRUE
is.array(temp4) # TRUE
```

**colMeans() vs. mean()**

@PaulHiemstra is right, instead of converting a vector to a single column for `colMeans()`

, it is much more common to just use `mean()`

on a vector. However, you are correct that `colMeans()`

is faster. I believe this is because it does a bit less checking for well-formed data, but we'd have to look at the internal C code to be sure. Consider this example:

```
# Create vector "v" and array "a"
n <- 10e7
set.seed(123) # Set random number seed to ensure "v" and "a[,1]" are equal
v <- runif(n)
set.seed(123) # Set random number seed to ensure "v" and "a[,1]" are equal
a <- array(runif(n), dim=c(n, 1))
# Test that "v" and "a[,1]" are equal
all.equal(v, a[,1]) # TRUE
# Functions to compare
f1 <- function(x = v){mean(x)} # Using mean on vector
f2 <- function(x = a){mean(x)} # Using mean on array
f3 <- function(x = a){colMeans(x)} # Using colMeans on array
# Compare elapsed time
system.time(f1()) # elapsed time = 0.344
system.time(f2()) # elapsed time = 0.366
system.time(f3()) # elapsed time = 0.166
```

`colMeans()`

on the array is faster than `mean()`

on either a vector or an array. However, most of the time this speed-up will be negligible. I find that it is more natural to just use `mean()`

on a vector or single-column array. But, if you are a true speed demon you might sleep better at night knowing that you are saving several hundred milliseconds of processing time by using `colMeans()`

on single column arrays instead.