Time complexity is measured as a function of the input instance size. The input instance size can be measured in bits. The input instance size increases as any of the inputs `U`

, `S`

, and `k`

increase. So the question that one is trying to answer is how much more time does it take to solve the problem of instance size for example `2n`

bits vs the problem of instance size `n`

.

So simply the size of the whole input instance has to increase and in this particular case it means increasing the size of `U`

and/or `S`

and/or `k`

.

To answer your two questions:

- Yes, the worst case time complexity is used: you are looking for the hardest problem of input size
`n`

and you correctly noticed that the problem (of the same size) probably becomes harder as you increase more parameters than just one.
It would be better to see the proof you are referring to but the thinking probably goes like:

I give a polynomial reduction of the set-covering decision problem instance of size `n`

to my problem's instance of size `m`

. If the size of the set-covering decision problem's input instance increases to `2n`

then the result of the reduction will be my problem's instance of size `2m`

because there is a direct correspondence between the input size of `U`

, `S`

, and `k`

and the input size of my problem.

So all set-covering decision problem instances of size `n`

map to my problem instances of size `m`

. Thus if I am looking for the hardest instance of the set-covering decision problem using this reduction I will find the hardest instance of my problem of size `m`

.

**EDIT**

From the proof in your linked paper:

Proof. We reduce an arbitrary 3-cover problem instance—in which we are
given a universe U, a family S of subsets of U, such that each subset
contains 3 elements, and we are asked whether we can (exactly) cover
all of U using |U|/3 elements of S—to a game with homogeneous
resources and schedules of size 3.

As you correctly say, they need to convert all instances of the set-cover problem to their problem. But they are using a reduction from a different problem: the Exact 3-cover problem that is proven to be NP-complete in *"Computers and intractability - MR Garey, DS Johnson, 1979"*.

The Exact 3-Cover problem is like the set cover decision problem but with `|U| = 3t`

and `S`

is a set of 3-element subsets of `U`

.