"Math Lotto" Tickets - finding the minimum winning set

Just to provide a concrete choice of 9 tickets that will have at least one winning ticket:

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Suppose to the contrary that all of these are losing tickets. The yellow ones forces 3 losing squares on the top half. Then 3 remaining losing squares will fill the bottom half. By pigeonhole, at least 2 of these losing squares will be in the bottom left 3x3 or the bottom right 3x3.

Say there are at least two losing squares in the bottom left 3x3, which means at most 1 losing square is in the bottom right 3x3. In this case one of the red tickets will not have a losing square, as the losing square is in one of the 3 columns.

And vice versa, if at least two losing squares are in the bottom right 3x3, then one of the purple tickets will not have a losing square.

Edit. A reference for this problem can also be found here https://www.cut-the-knot.org/pigeonhole/MathLotto.shtml


Here is a proof that, given a set of 8 tickets, we can always find 6 losing squares such that each ticket has marked at least one losing square.

If there is a square that is marked on 3 tickets, we choose that square along with one square from each of the other 5 tickets to be losing. So suppose instead that each square is marked on at most 2 tickets. By the pigeonhole principle, there must be a square marked on exactly two tickets; call it Square A. The remaining 6 tickets avoid square A, so applying the pigeonhole principle again, there must be a different square marked on two of the remaining 6 tickets; call it Square B. As losing squares, we then choose Square A, Square B, and one square from each of the remaining 4 tickets.

A very similar argument can prove that, if we have a collection of 9 tickets with the property that at least one will be a winner, then no square can be marked on 3 or more of those tickets.