Ok, you have the number of rectangles with integer coordinates between the points (0, 0)
, (x, 0)
, (x, y)
and (0, y)
, x
and y
being integers too. You now need to remove the perfect squares from this sum.
To compute it, let's evaluate the number of squares 1*1
: there are obviously x*y
of them. For squares 2*2
, we have x-1
choices for the x-coordinate and y-1
for the y-coordinate of the bottom left-hand corner of such a square, due to the width of this square: this results in (x-1)*(y-1)
squares. Idem, we will have (x-2)*(y-2)
squares 3*3
, etc.
So for a given i
, we have (x - i + 1) * (y - i + 1)
squares i*i
, and i
goes from 1
to the minimum of x
and y
(of course if x
is 4 and y
is 7, we cannot have a square with a side greater than 4).
So if m = min(x, y)
, we have:
Sum_Squares = Sum(i = 1, i = m, (x - i + 1) * (y - i + 1))
= Sum(j = 0, j = m - 1, (x - i) * (y - i))
= Sum(j = 0, j = m - 1, x*y - (x+y)*j + j^2)
= m*x*y - (x+y)*Sum(j = 0, j = m - 1, j) + Sum(j = 0, j = m - 1, j^2)
= m*x*y - (x+y)*Sum(j = 1, j = m - 1, j) + Sum(j = 1, j = m - 1, j^2)
= m*x*y - (x+y)*m*(m-1)/2 + (m-1)*m*(2*m-1)/6
I get that with an index change (j = i - 1
) and via the well-known formulas:
Sum(i = 1, i = n, j) = n*(n + 1)/2
Sum(i = 1, i = n, j^2) = n*(n + 1)*(2*n + 1)/6
You just have to remove this Sum_Squares
from (x^2+x)(y^2+y)/4
and you're done !