# An algorithm to solve a square sum problem

I found the following unsolved problem:

A 4x4-square of integers contains 30 subsquares A_i. Let B_i be the sum of integers (or elements) of A_i. What is the maximum number j such that for all positive k < j we have that k in \${B_1,...,B_{30}}\$? And what is an example of such 4x4 square?

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ARe there restrictions on the integers that are contained? eg do they have to be positive or non-negative or anything like that? –  Chris Sep 19 '11 at 16:11
It does not matter if they are positive or negative or zero. Just integers. –  amateurprogrammer Sep 19 '11 at 16:12
I don't think j has been correctly explained. You state it must be greater than k, and also the maximum possible number that meets that criteria - surely that's just positive infinity. –  Gareth Deli Sep 19 '11 at 16:22
If it is a positive infinity, how can you create 40 different integers such that they all belongs to set which have 30 integers? –  amateurprogrammer Sep 19 '11 at 16:27
@Gareth: no, it says for any positive k < j, k is the sum of a subsquare. Probably should say "all" k but the meaning is clear. –  Tom Zych Sep 19 '11 at 16:55

To start (and as an example), with A =

``````8  2  5  6
3  4  7  1
9  10 11 12
13 14 15 16
``````

I get j = 20

It gives a lower bound for j:

20 <= j <= 31

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A simple cardinality argument shows that j = 31 is an upper bound.

We can easily show that J = 30 is also an upper bound by noting that in the j = 31 case every sum must be a unique integer in the range [1,30]. Since every element in the 4x4 square is a unique integer > 0, the sum of the entire square is at least 120. Since that isn't in the range [1,30], there are no squares where j = 31.

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If you read the question carefully, you will see that the integers are not necessary distinct and I don't see any reason why all of then must be positive. –  Jaakko Seppälä Jun 29 '13 at 19:04