Here's a vectorized solution for inserting vector `q`

into vector `p`

after every `n`

elements:

```
N = numel(p);
M = mod(N, n);
p_pad = [p(:); zeros((n - M) * (M > 0), 1)];
res = [reshape(p_pad, n, []); repmat(q(:), 1, numel(p_pad) / n)];
res = res(1:N + numel(q) * fix(N / n));
```

You can retain the input vector row/column property for the output by adding the following:

```
if isrow(p)
res = res';
end
```

### Explanation

It's easiest to explain this with an example. We start out with vector `p`

, and we want to reshape it into an matrix, each column having `n`

elements. If the number of elements in `p`

is not a multiple of `n`

, we'll need to "pad" it (say, with zeroes). For example, for `p = [1 2 3 4 5 6 7], n = 3`

, we'll reshape `p`

to the following matrix:

```
1 4 7
2 5 0
3 6 0
```

Now we use `repmat`

to replicate vector `q`

and generate another matrix with the same number of columns, where each column is `q`

:

```
9 9 9
9 9 9
```

Then we concatenate these two matrices vertically (in my code the new matrix is called `res`

):

```
1 4 7
2 5 0
3 6 0
9 9 9
9 9 9
```

And after we turn this matrix into a vector once again, concatenating column together, we should get the desired result. Note that we also want to discard the trailing `0 0 9 9`

(that formed due to the padding), so let's compute the expected amount of elements `L`

in the result:

```
L = N + length(q) * fix(N / n)
```

and then extract we'll just extract the first `L`

elements from our `res`

.

It's usually easiest to operate on columns because MATLAB's linear indexing is column-major.

### Examples

Let's put this into a function:

```
function y = insertn(p, q, n)
N = numel(p);
p_pad = [p(:); zeros((n - mod(N, n)) * (mod(N, n) > 0), 1)];
y = [reshape(p_pad, n, []); repmat(q(:), 1, numel(p_pad) / n)];
y = y(1:N + numel(q) * fix(N / n));
if isrow(p)
y = y';
end
```

Now let's test it for different inputs:

```
>> insertn(0:5, [9 9], 2)
ans =
0 1 9 9 2 3 9 9 4 5 9 9
>> insertn(1:3, [9 9], 2)
ans =
1 2 9 9 3
>> insertn(1:7, [9 9], 3)
ans =
1 2 3 9 9 4 5 6 9 9 7
```