#math trivia for #September2: #245 can be expressed as a^2+b^2+c^2 for positive integers a, b, c in three ways. What are they?

— Burt Kaliski Jr. (@modulomathy) September 3, 2013

The three ways are

- 1
^{2}+10^{2}+12^{2} - 2
^{2}+4^{2}+15^{2} - 8
^{2}+9^{2}+10^{2}

The third way is an interesting one because the integers are consecutive. If we let *x* denote the middle integer, then the sum of the squares would be

(*x*-1)^{2}+*x*^{2}+(*x*+1)^{2} = *x*^{2}-2*x*+1+*x*^{2}+*x*^{2}+2*x*+1 = 3*x*^{2}+2 .

Any number that is two more than three times a square can thus be expressed as the sum of squares of three consecutive integers. To meet the constraint that the integers must be positive, the number must be at least 1^{2}+2^{2}+3^{2} = 14. (The relationship also holds for the numbers 3 and 5, if non-positive integers are allowed.)

Note: If we relaxed the constraint that the integers must be positive in the present problem, one more way would be possible: 7^{2}+14^{2}. This is a nice consequence of the fact that 245 is the product of a sum of squares, 5, and a square, 49.