Difference between revisions of "Bezout's Lemma"
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Revision as of 18:31, 4 September 2008
Bezout's Lemma states that if two integers and satisfy , then there exist integers and such that . In other words, there exists a linear combination of and equal to .
Proof
Since , . So is the first time that , and it is there that the modular residues begin repeating. Now if for all integers , we have that , then one of those integers must be 1 from the Pigeonhole Principle. Assume for contradiction that . Thus it repeats, and one of or must be , which is opposite of what we had. Thus there exists an such that , and the same proof holds for .
Since is equivalent to 1 mod x and mod y, and , . Lets say that for some integer . We can subtract from and plug that in to get
.
Thus there does exist integers and such that .
See also
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