Just use `nchoosek`

and a double `for`

-loop to go through all possible combinations of elements in `B`

:

```
SA = sum(A);
for k = 1:numel(B)
for idx = nchoosek(1:numel(B), k)'
B_subset = B(idx);
if (SA + sum(B_subset) <= 2000)
disp([A(:)', B_subset(:)'])
end
end
end
```

This prints all combinations with a sum less than (or equal to) 2000. For your example we get:

```
10 40 90 130 200 260 320 100
10 40 90 130 200 260 320 300
10 40 90 130 200 260 320 500
10 40 90 130 200 260 320 100 300
10 40 90 130 200 260 320 100 500
10 40 90 130 200 260 320 300 500
10 40 90 130 200 260 320 100 300 500
```

## Explanation:

**The inner **`for`

-loop:

The inner `for`

-loop uses `nchoosek(1:numel(B), k)`

, which generates all k-length combinations out of 1...length(B) (I'm using `numel`

instead of `length`

out of habit; in this case it has the same effect). For example, in our case `B`

has 4 elements, so for `k = 3`

we get `nchoosek(1:4, 3)`

:

```
1 2 3
1 2 4
1 3 4
2 3 4
```

What we get from this is all the possible k-length combinations of indices of elements in `B`

. In each iteration, this `for`

-loop assigns a different combination of indices to `idx`

. How do we convert the indices of `B`

to real elements? We simply write `B(idx)`

.

Inside loop the combination is tested: if the total `sum(A) + sum(B(idx))`

is less than (or equal to) 2000, that combination is displayed.

**The outer **`for`

-loop:

The outer `for`

-loop simply iterates over all possible lengths of combinations (that is, over all possible values of `k`

).

Hope that helps!

## P.S:

Some MATLAB programming tips for the future:

1. Variable names are case-sensitive.

2. You don't need to increment the loop variable. The `for`

loop does that automatically for you.