I am already able to prove that $g \mid s$ assuming $x+y=s$ and $(x,y)=g$, but I am having some trouble showing that assuming $g \mid s$, there exists an $x$ and $y$ such that $x+y=s$ and $(x,y)=g$. So far, I've started with saying that $g \mid 0$ necessarily. Therefore we also know that $g \mid (0x+sy)$. I'd like to be able to set the values of $x$ and $y$ to something to show that there exist an $x$ and a $y$ that satisfy $x+y=s$ and $(x,y)=g$, but I'm not really sure where to go from here. Can anyone offer any help?
If $s$ and $g>0$ are integers, how can I prove that $x$ and $y$ exist satisfying $x+y=s$ and $(x,y)=g$ if and only if $g \mid s$?
3
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elementary-number-theory
divisibility
2 Answers
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HINT. $(gn,g) = g(n,1)=g$.
The converse follows because $a|b$ and $a|c$ implies $a|b+c$.
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1I'm not sure I understand what your hint is referring to. Can you offer a little more clarification please? – 2011-02-02
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0@user6548: $gn+g = g(n+1)$. If $g|s$, can you write $s$ as $g(n+1)$ for some $n$? – 2011-02-02
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0I'm very sorry, but I'm still having trouble wrapping my head around how this fits in. Does this eliminate the need to mention that g|0 and thus, the need to mention that g|(0x+sy)? If not, how do these follow one another? – 2011-02-02
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0@user6548: If $g|s$, then $s=gd$ for some $d$. Write $d=(d-1)+1$. Can you now write $s$ as the sum of $gn$ and $g$ for some $n$? – 2011-02-02
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0Ah, that clears things up perfectly. Thank you. – 2011-02-02
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$\rm\ \ g = (x,s-x) = (x,s)\ \iff\ 1 = (x/g,\:s/g)\:,\ $ so choose $\rm x/g\ $ coprime to $\rm s/g\:,\ $ e.g. $\rm\ s/g + 1$