Euclid's lemma

From Wikipedia, the free encyclopedia

Euclid's lemma (Greek λῆμμα) is a generalization of Proposition 30 of Book VII of Euclid's Elements. The lemma states that

If a positive integer divides the product of two other positive integers, and the first and second integers are coprime, then the first integer divides the third integer.

This can be written in notation:

If n|ab and gcd(n,a) = 1 then n|b.

Proposition 30, also known as Euclid's first theorem, states:

If a prime number divides the product of two positive integers, then the prime number divides at least one of the positive integers.

That can be written as:

If p|ab then p|a or p|b.

Often, proposition 30 is called Euclid's lemma instead of the generalization. A lemma is a "mini" theorem that is proven and used to prove a bigger theorem. Most of the time in mathematics textbooks Euclid's lemma is used to prove the fundamental theorem of arithmetic.

[edit] Proof of Proposition 30

Say p is a prime factor of ab, but also state that it is not a factor of a. Therefore, rp = ab\!, where r is the other corresponding factor to produce ab. As p is prime, and also because it is not a factor of a, a and p must be coprime. This means that two integers x and y can be found so that 1 = px + ay\! (Bézout's identity). Multiply with b on both sides:

b = b(px + ay)\!
b = bpx + bay\!.

We stated previously that rp = ab\!, and so:

b = bpx + rpy\!
b = p(bx + ry)\!.

Therefore, p is a factor of b. This means that p must always exactly divide either a or b or both. Q.E.D.

[edit] Example

Euclid's lemma in plain language says: If a number N is a multiple of a prime number p, and N = a · b, then at least one of a and b must be a multiple of p. Say,

N = 42\!,
p = 7\!,

and

N = 14 \cdot 3\!.

Then either

x \cdot 7 = 14\!

or

x \cdot 7 = 3\!.

Obviously, in this case, 7 divides 14 (x = 2).

[edit] See also