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I found part of my answer here: If g(f(x)) is one-to-one (injective) show f(x) is also one-to-one (given that...); however I wanted to flesh out the last two statements I had in a proposition in my notes.

Proposition: Let $f: A \rightarrow B$ and $g: B \rightarrow C$. Then:

(i) If $g \circ f$ is one-to-one, then $f$ is one-to-one.

(ii) If $g \circ f$ is onto, then $g$ is onto.

Proof: (i) Suppose $f(x)=f(y)$ for some $x,y$.

Since $g \circ f$ is one-to-one: $g\circ f(x) = g\circ f(y) \Rightarrow x=y,\forall x,y \in A.$

Therefore $f$ must be one-to-one.

(ii) Since $g \circ f (x)$ is onto, then for every $c \in C$ there exists an $a \in A$ such that $c=g(f(a))$. Then there exists a $b \in B$ with $b=f(a)$ such that $g(b)=c$. Thus g is onto.

I wanted to confirm that these proofs are both correct for my peace of mind (as they weren't proven in class).

3 Answers 3

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Both of your proofs are correct.

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    Thanks. I'm trying to $f$lesh out all the details on various propositions that my professor had left for me to prove. I'm finding that I am getting stuck on these relatively short ideas.2012-09-28
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I've never taken an analysis course but I don't believe that your first proof is correct. Since take for example $f=x^2$, which isn't one-to-one. $g \circ f (-2)$ and $g \circ f (2)$ would be equal, since in both cases it is $g(4)$ and $g$ is a function. So $x$ would not have to equal $y$ and thus $f$ does not have a requirement of being one-to-one for the composition $g(f(x))$ to be one to one. However I do believe that $g$ would have to be one to one for that to be the case. Please correct me if I am wrong. Just my two cents.

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    As @kb414 notes above, your argument actually gives that $g \circ f$ is _not_ one-to-one precisely because $f$ is not one-to-one. (And thus also contains the essential elements of a general proof that if $f$ is not one-to-one, then neither is $g \circ f$.)2013-09-03
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On the first one i would say since g composed of f is one-to-one, if g(f(x))=g(f(y)) for all x,y in A then x=y. By definition of f then there exist some value f(x) and f(y) in B. Then because we already noted x=y. F(x) must equal F(y) by the definition of a function.