I am trying to find an optimal algorithm that can find the largest subset where the sum of the elements is the lowest while covering all elements.

eg :- Imagine A B C are retailers and W X Y Z are products, the goal is to minimize the visits, and lower the price.

```
A B C
W 4 9 2
X 1 3 4
Y 9 3 9
Z 7 1 1
So it appears my top two choices are
a) B:{XYZ} - 7 C:{W} - 2
b) C:{WXZ} - 7 B:{Y} - 3
So a) is picked because since it has a lower cost, i.e 9.
```

This problem seems similar to vertex cover and other linear programming algorithms, but I can't figure out the right one.

Update:

It seems I need to add an additional variable. Introducing t. If the cost of visiting fewest retailers and the next fewest is > t, the next former is picked.

```
Continuing with the example.
say t = 5,
The largest subset containing all elements would be B:{WXYZ} with a cost of 16.
The next largest subset(s) is B:{XYZ} - 7 C:{W} - 2 with a cost of 9.
t = 16 - 9 > 5. So we pick B:{XYZ} - 7 C:{W} - 2
but if we did A:{X}, B:{Y}, C:{WZ} - 5, t = 9 - 5 < 5.
So B:{XYZ} - 7 C:{W} - 2 is picked
```

Really I'm just interested if there is already an algorithm that fits this pattern. I can't be the first person that needs this sort of optimization.

`C:{WXYZ}`

(fewer visits) or`A:{X}, B:{Y}, C:{WZ}`

(lower cost) could not be picked instead of`B:{XYZ}, C:{W}`

. – btilly Jun 26 '13 at 6:29