Here's a do-it-yourself method that made me giggle with delight, using `nchoosek`

, although it's *not* better than @Luis Mendo's accepted solution.

For the example given, after 1,000 runs this solution took my machine on average 0.00065935 s, versus the accepted solution 0.00012877 s. For larger vectors, following @Luis Mendo's benchmarking post, this solution is consistently slower than the accepted answer. Nevertheless, I decided to post it in hopes that maybe you'll find something useful about it:

**Code:**

```
tic;
v = {[1 2], [3 6 9], [10 20]};
L = [0 cumsum(cellfun(@length,v))];
V = cell2mat(v);
J = nchoosek(1:L(end),length(v));
J(any(J>repmat(L(2:end),[size(J,1) 1]),2) | ...
any(J<=repmat(L(1:end-1),[size(J,1) 1]),2),:) = [];
V(J)
toc
```

gives

```
ans =
1 3 10
1 3 20
1 6 10
1 6 20
1 9 10
1 9 20
2 3 10
2 3 20
2 6 10
2 6 20
2 9 10
2 9 20
Elapsed time is 0.018434 seconds.
```

**Explanation:**

`L`

gets the lengths of each vector using `cellfun`

. Although `cellfun`

is basically a loop, it's efficient here considering your number of vectors will have to be relatively low for this problem to even be practical.

`V`

concatenates all the vectors for easy access later (this assumes you entered all your vectors as rows. v' would work for column vectors.)

`nchoosek`

gets all the ways to pick `n=length(v)`

elements from the total number of elements `L(end)`

. **There will be more combinations here than what we need.**

```
J =
1 2 3
1 2 4
1 2 5
1 2 6
1 2 7
1 3 4
1 3 5
1 3 6
1 3 7
1 4 5
1 4 6
1 4 7
1 5 6
1 5 7
1 6 7
2 3 4
2 3 5
2 3 6
2 3 7
2 4 5
2 4 6
2 4 7
2 5 6
2 5 7
2 6 7
3 4 5
3 4 6
3 4 7
3 5 6
3 5 7
3 6 7
4 5 6
4 5 7
4 6 7
5 6 7
```

Since there are only two elements in `v(1)`

, we need to throw out any rows where `J(:,1)>2`

. Similarly, where `J(:,2)<3`

, `J(:,2)>5`

, etc... Using `L`

and `repmat`

we can determine whether each element of `J`

is in its appropriate range, and then use `any`

to discard rows that have any bad element.

Finally, these aren't the actual values from `v`

, just indices. `V(J)`

will return the desired matrix.