A general solution to this problem is NP-complete, because it subsumes the knapsack problem. However, as with the knapsack problem, you may be able to address it constructively (in "pseudopolynomial time") using dynamic programming.

To see this: given a knapsack problem with knapsack size `T`

and object sizes `c[i]`

, compose a problem as described in your question such that `a[i]==b[i]==c[i]`

and `k == sum(c[i]) - T`

.

Then, the solution to the knapsack problem is the set of indices *not* in `S`

:

```
sum(c[i] *not* indexed by S) == sum(c[i]) - sum(a[i] indexed by S)
T == sum(c[i]) - k
```

Note that `S`

satisfies knapsack constraint `sum(c[i] *not* indexed by S) <= T`

if and only if the problem constraint `sum(a[i] indexed by S) >= k`

holds.

```
sum(c[i] *not* indexed by S) == sum(c[i]) - sum(b[i] indexed by S)
```

Since a solution to the posed problem minimizes `sum(b[i] indexed by S)`

over valid S, `sum(c[i] *not* indexed by S)`

is maximized over valid S, and is an optimal solution of the knapsack problem.