Each of A, B and C is a prime number with A ≤ B ≤ C.

Determine all possible triplet(s) (A, B, C) such that:

(i) A² + B² + C² is a prime number, and:

(ii) C⁶ does not leave a remainder of 1 when divided by 14.

As Daniel rightly points out, condition 2 means in substance that c is 7 or a number oddly divisible by 7 (so not prime). C is therefore 7. All 3 squares cannot be the same, as P would then be divisible by 3. Further, P cannot be of the form 4k+1, since this would require a, b to be even. a, b would then have to be 2, giving the result 57, which is not prime. Since primes that are sums of 3 squares are congruent to 1,3,or 5 mod 8, P must be of the form 8k+3.  This gives:

(2k1-1)^2+(2k2-1)^2=8k-46  k1>1,k2>1, k<18

for which there are 11 integer solutions, of which all but 3,3,7,67; 3,5,7,83; and 3,7,7,107 can readily be eliminated.

 

Edited on September 10, 2010, 12:21 am

Posted by broll on 2010-09-09 16:25:01