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Matt Valeriote (McMaster University) Fermat’s Last Theorem 26 January, 2017 1 / 14 Fermat’s Last Theorem Matt Valeriote McMaster University 26 January, 2017 Matt Valeriote (McMaster University) Fermat’s Last Theorem 26 January, 2017 2 / 14 The Pythagorean Theorem Theorem The square of the hypotenuse of a right angle triangle is equal to the sum of the squares of the other two sides. Note In other words, if we have a right angle triangle with c = the length of the hypotenuse, and a and b are the lengths of the other two sides, then a2 + b 2 = c 2 . Matt Valeriote (McMaster University) Fermat’s Last Theorem 26 January, 2017 3 / 14 Proof Matt Valeriote (McMaster University) Fermat’s Last Theorem 26 January, 2017 4 / 14 Pythagorean Triples Pythagorean triples Any triple of natural numbers (a, b, c) that satisfy a2 + b 2 = c 2 is called a Pythagorean triple. Note So, the following are Pythagorean triples: (3, 4, 5), (5, 12, 13), (8, 15, 17), (9, 12, 15). Definition A Pythagorean triple (a, b, c) is primitive if the number 1 is the only common divisor of a, b, and c, i.e, they are relatively prime. Matt Valeriote (McMaster University) Fermat’s Last Theorem 26 January, 2017 5 / 14 The Pythagorean Triples Theorem Note There are an infinite number of (primitive) Pythagorean triples, and the following theorem provides a way to generate all of them. Theorem Let m > n be relatively prime natural numbers with one of them even, and one of them odd. Then (2mn, m2 − n2 , m2 + n2 ) is a primitive Pythagorean triple, and Every primitive Pythagorean triple is of this form. Notes It follows that if (a, b, c) is a primitive Pythagorean triple, then c is odd, and exactly one of a and b is even, and every Pythagorean triple is of the form: (k · (2mn), k · (m2 − n2 ), k · (m2 + n2 )) for some integer k. Matt Valeriote (McMaster University) Fermat’s Last Theorem 26 January, 2017 6 / 14 Fermat’s Last Theorem Note In contrast to the equation x 2 + y 2 = z 2 , which we have seen has an infinite number of solutions over the natural numbers, the cases where we replace the exponent 2 in this equation with larger exponents is strikingly different. Fermat’s Last Theorem If n > 2 then there are no positive integers a, b, and c such that an + b n = c n . Notes This theorem was claimed by Pierre de Fermat in 1637, but he did not provide a general proof. Fermat did provide a proof for the case n = 4. In 1994 Andrew Wiles produced a proof of the full theorem. Matt Valeriote (McMaster University) Fermat’s Last Theorem 26 January, 2017 7 / 14 A Reduction Note Suppose that the triple (a, b, c) is a solution to the equation x 15 + y 15 = z 15 . Then (a3 , b 3 , c 3 ) is a solution to the equation x 5 + y 5 = z 5. So, if x 5 + y 5 = z 5 has no whole number solution, then neither does x 15 + y 15 = z 15 . Theorem If Fermat’s Last Theorem holds for n = 4 and for all odd prime numbers n, then Fermat’s Last Theorem holds for all n > 2. Matt Valeriote (McMaster University) Fermat’s Last Theorem 26 January, 2017 8 / 14 The case n = 4 Theorem (Fermat) There are no positive integers a, b, and c such that a4 + b 4 = c 4 . Note To prove this theorem, we instead prove the following stronger statement from which the n = 4 case of Fermat’s Last Theorem will follow: there are no positive integers x, y , and w such that x 4 + y 4 = w 2. (Since if a4 + b 4 = c 4 then x = a, y = b, w = c 2 would be a solution to x 4 + y 4 = w 2 .) Matt Valeriote (McMaster University) Fermat’s Last Theorem 26 January, 2017 9 / 14 The equation x 4 + y 4 = w 2 Proof: This proof makes use of a technique, called the method of infinite descent, introduced by Fermat. We start with the assumption that x, y , and w are positive integers that satisfy the equation such that w is as small as possible amongst all of the positive integer solutions to the equation. We then produce new positive integers r , s, and t that are also a solution to the equation, but with t < w . This will contradict the minimality of w , and so we conclude that the equation cannot have any positive integer solutions. Matt Valeriote (McMaster University) Fermat’s Last Theorem 26 January, 2017 10 / 14 Case 1: A common factor Proof: In this case, we assume that two of the numbers x, y , and w of our solution have a common factor greater than 1. We may assume that this common factor is some prime number p. It follows that since p divides two of x, y , and w , then it divides all three of them. For example, if p divides x and y , then p will also divide x 4 + y 4 and so p will divide w 2 . Since p is prime, then p will actually divide w . So, we may assume that p divides each of x, y , and w . Then, p 4 divides x 4 + y 4 and so p 4 divides w 2 . Since p is prime, then in fact, p 2 divides w . Then r = x/p, s = y /p and t = w /p 2 are positive integers and a solution to the equation (check), with t < w . Matt Valeriote (McMaster University) Fermat’s Last Theorem 26 January, 2017 11 / 14 Case 2: No common factors Proof. In the remaining case, we assume that no two of x, y , and w share a common factor greater than 1. Then x 2 , y 2 , and w do not share a common factor greater than 1. Thus, since x 4 + y 4 = w 2 then (x 2 , y 2 , w ) is a primitive Pythagorean triple. From an earlier theorem, we know that there are relatively prime natural numbers p and q with one odd, and the other even so that: y 2 = 2pq, x 2 = p2 − q2, w = p2 + q2. Then x 2 + q 2 = p 2 and so (x, q, p) is another primitive Pythagorean triple (with p odd and q even). Matt Valeriote (McMaster University) Fermat’s Last Theorem 26 January, 2017 12 / 14 Case 2: No common factors Proof. Using primitive Pythagorean triples theorem, there are relatively prime natural numbers m and n with one even and one odd so that: q = 2mn, x = m2 − n2 , p = m2 + n2 . Using that y 2 = 2pq and that 2q and p are relatively prime, then both 2q and p are squares. So p = t 2 for some positive integer t. But, 2q = 4mn and since m and n are relatively prime, then m and n are each squares. Thus m = r 2 and n = s 2 for some positive integers r and s. Using that m2 + n2 = p, we conclude that r 4 + s 4 = t 2 and so r , s, and t is a solution to the equation. Finally, we note that t ≤ p < p 2 + q 2 = w , a contradiction. Matt Valeriote (McMaster University) Fermat’s Last Theorem 26 January, 2017 13 / 14 Matt Valeriote (McMaster University) Fermat’s Last Theorem 26 January, 2017 14 / 14
