Fermat's Four Squares Theorem

Abstract

It is easy to find a right-angled triangle with integer sides whose area is 6. There is no such triangle with area 5, but there is one with rational sides (a `Pythagorean triangle'). For historical reasons, integers such as 6 or 5 that are (the squarefree part of) the area of some Pythagorean triangle are called `congruent numbers'. These numbers actually are interesting for the following reason: Notice the sequence 14, 614, 1214. It is an arithmetic progression with common difference 6, consisting of squares (12)2, (52)2, (72)2 of rational numbers. Indeed the common difference of three rational squares in AP is a congruent number and every congruent number is the common difference of three rational squares in arithmetic progression. The triangle given by 92+402=412 has area 180=5·62 and the numbers x-5, x and x+5 all are rational squares if x=1197/144. Recall one obtains all Pythagorean triangles with relatively prime integer sides by taking x=4uv, y=(4u2-v2), z=4u2+v2 where u and v are integers with 2u and v relatively prime. Fermat proved that there is no AP of more than three squares of rationals.