Three positive integers a, b, c such that a2 + b2 = c2 are said to form a Pythagorean triple. The name comes from the Pythagorean Theorem, which states that any right triangle with integer side lengths yields a Pythagorean triple. The converse is also true: every Pythagorean triple determines a right triangle with the given side lengths.
For example:
a b c 3 4 5 6 8 10 5 12 13 9 12 15 8 15 17 7 24 25If (a,b,c) is a Pythagorean triple so is (da,db,dc) for any positive integer d. A Pythagorean triple is said to be primitive if a, b and c have no common divisor. The triangles described by non-primitive Pythagorean triples are always proportional to the triangle described by a smaller primitive Pythagorean triple.
If m > n are positive integers, then
A good starting point for exploring Pythagorean triples is to recast the original equation in the form:
By contrast the number 1229779565176982820 is the lowest integer in exactly 15386 primitive triples, the smallest and largest triples it is part of are:
1229779565176982820
1230126649417435981
1739416382736996181
and
1229779565176982820
378089444731722233953867379643788099
378089444731722233953867379643788101.
For the curious, consider the prime factorisation of 1229779565176982820 = 22 * 3 * 5 * 7 * 11 * 13 * 17 * 19 * 23 * 29 * 31 * 37 * 41 * 43 * 47. The number of prime factors is related to the large number of primitive Pythagorean triples. Note that there are larger integers that are the lowest integer in an even greater number of primitive Pythagorean triples.
Fermat's Last Theorem states that non-trivial triples analogous to Pythagorean triples but with exponents higher than 2 don't exist.
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