64 and 36.
The proposition in the question is simply not true so there can be no answer!For example, if given the integer 6:there are no two perfect squares whose sum is 6,there are no two perfect squares whose difference is 6,there are no two perfect squares whose product is 6,there are no two perfect squares whose quotient is 6.
Yes. 6 squared+71 squared equals 5077
Only 25 which is, 52 = 32 + 42 (25 = 9 + 16)
It is Fermat's theorem on the sum of two squares. An odd prime p can be expressed as a sum of two different squares if and only if p = 1 mod(4)
64 and 36.
The proposition in the question is simply not true so there can be no answer!For example, if given the integer 6:there are no two perfect squares whose sum is 6,there are no two perfect squares whose difference is 6,there are no two perfect squares whose product is 6,there are no two perfect squares whose quotient is 6.
5
Yes. 6 squared+71 squared equals 5077
Only 25 which is, 52 = 32 + 42 (25 = 9 + 16)
The sum of their squares is 10.
split 10 in two parts such that sum of their squares is 52. answer in full formula
It is Fermat's theorem on the sum of two squares. An odd prime p can be expressed as a sum of two different squares if and only if p = 1 mod(4)
Two. 36, and 49 are perfect squares.
This is when two perfect squares(ex.) [x squared minus 4] a question in which there are two perfect squares. you would find the square root of each. then it depends on what kind of math your doing.
85
Sum of squares? Product?