The set cover optimization problem is: given a universe `U`

and a set `S`

of subsets of `U`

(i.e. S \subsetof 2^U), find the minimal subset `C`

of `S`

such that the union of its elements is `U`

. Known to be NP-hard.

The variation I am interested in is, given the same things (`U`

and `S`

), find the minimal subset `C`

of `S`

such that `C`

is a cover, and also for some (unspecified) element `u`

in `U`

, all sets in `S`

containing `u`

are in `C`

.

The problem I'm applying this to is: given a set of symptoms I'm seeing (`U`

), I have potential causes for these problems (`S`

- each element of `S`

is corresponds to a "cause" of potentially multiple symptoms). I want the least number of causes that can cause all the symptoms I'm seeing, and I also want to have the result that removing all of these "cause"s will also cause at least one symptom to be solved.

Does anyone have any good ideas on whether this is any easier than the original problem?

**EDIT to include solution (incorporating comments)**

It is at least as hard as set cover.

`SetCover(U,S)`

can be solved via `SetCoverNew(U + {w}, S + {{w}})`

with `w`

being an element not in `U`

and `+`

denoting set union.

Any solution of the given SetCoverNew instance must include the set `{w}`

(otherwise it is not a set cover of `U + {w}`

).

It is claimed that a solution of the `SetCover(U,S)`

is `X = SetCoverNew(...) \ {{w}}`

. First, `X`

must be a cover of `U`

, otherwise `X + {{w}}`

cannot be a cover of `U + {w}`

. Secondly, `X`

must be a minimal cover of `U`

, otherwise, `SetCover(U,S) + {{w}}`

is a cover of lower cardinality than `SetCoverNew(...)`

.