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If $A$, $B$, and $C$ are topological groups, and $f: A \to B$ and $g: B \to C$ are two continuous group homomorphisms, what does it usually mean for

$1 \to A \stackrel{f}{\to} B \stackrel{g}{\to} C \to 1$

to be exact?

I would expect that one at least expects exactness as abstract groups (as opposed to, say $g(B)$ just being dense in $C$).

Does one also expect $f$ to be a homeomorphism of $A$ onto $f(A)$? And if so, does one further expect $C$ to be homeomorphic to $B/f(A)$ with the quotient topology>?

Would one's expectations change if $A$, $B$, and $C$ were all abelian topological groups? (And what if they were all topological $G$-modules for some topological group $G$ -- that is, if each was an abelian topological group and additionally we had continuous group action maps $G \times A \to A$ and same for $B$ and $C$, and $f$ and $g$ were $G$-equivariant?)

This seems to just be a question of semantics. I definitely see at least some authors require $A$, $C$ to have the subspace, quotient topology. But then something I read somewhere else seems to suggest that the condition should only be on the topology of $A$ only, or maybe no additional topological condition at all --- I can't quite tell...

So, what do you expect when you read or hear that $1 \to A \to B \to C \to 1$ is an exact sequence of topological groups? Is there a consensus?

UPDATE: The question has been reduced to understanding what it means for a sequence to be exact in a category that is not abelian but has kernels and cokernels (and a zero object). There are some ideas in Matthew Daws's answer and the following comments below, but a reference would be great.

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    @Aaron: The categories I'm interested in at the moment all have zero objects as well as kernels and cokernels. They're often even additive. They're just not normal, so that requiring $\mathop{\rm coker} f = g$ (Matthew Daws's suggestion below) is more restrictive than $\ker (\mathop{\rm coker} f) = \ker g$ (my suggestion below)...2019-03-30

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Edit: Added some references; thanks to t.b. for many of these.

Suppose I take as my category topological (Hausdorff) groups and continuous homomorphisms. This has a "zero object"-- just the trivial group $\{1\}$. Then the (group theoretic) kernel of a continuous homomorphism will be a closed subgroup, and hence a topological group in its own right. It's easy to see that this shows that this category has "kernels" in the abstract sense.

Forming cokernels is a little trickier: given $f:G\rightarrow H$ let $Q$ be the closed normal subgroup of $H$ generated by $f(G)$. Then $H/Q$ is a Hausdorff topological group as well (See Hewitt+Ross, Thm. 5.26). The cokernel of $f$ is then the quotient homomorphism $q:H\rightarrow H/Q$. Indeed, clearly $qf=0$; if q'f=0 then f(G) \subseteq \ker q' and so as \ker q' is a closed normal subgroup, Q\subseteq \ker q'.

Similarly, $f:G\rightarrow H$ is "monic" if and only if $f$ is (set-theoretic) injective. $f$ is "epi" if it has dense range (Edit: the "only if" claim fails for locally compact groups, see an example of Reid; but it's true for locally compact groups in the category of Hausdorff groups, see a paper of Nummela, "On epimorphisms of topological groups" (1978); for merely Hausdorff topological groups, "only if" is false, see paper of Uspenskij).

I then believe that we have an abstract, category-theoretic definition of "exact sequence", namely $ 0 \rightarrow G \xrightarrow{f} H \xrightarrow{g} K \rightarrow 0 $ with $f$ monic, $g$ epi, $f$ is the kernel of $g$ and $g$ is the cokernel of $f$. Translating, this means precisely that $f$ is a homeomorphism onto its range, which is the usual kernel of $g$, and $K$ is isomorphic to $H/f(G)$, with $g$ the quotient map. This definition is copied from Mac Lane, "Categories for the working mathematician", Chapter VIII, Section 3. Now, that section is all about abelian categories, but the definition works in more generality.

Is this the "correct" definition? I absolutely wouldn't want to say that. But if you wanted something to start with, this seems reasonable. If you want something slightly different for an application? Then what's wrong with just spelling out, very clearly, what you mean by "exact", and maybe saying something to the effect that this is not an entirely standard defintion?

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    @t.b. (and Matt) Just seen this - there is a book of Borceux and Bourn that sets up things like exact sequences for very general categories - I think the book is called "Homological categories" or similar. I've never read it but they definitely consider certain kinds of non-additive category (such as Grp and its relatives)2012-01-14
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In an additive (or even preadditive) category, a map $\phi: A \to B$ is proper if the natural map from the kernel of the cokernel of $\phi$ to the cokernel of the kernel of $\phi$ is an isomorphism. Note that part of this definition is the requirement that all these kernels and cokernels exist. In this case, both objects are sometimes called the "image" (though various sources mean one or the other in general). Usually a sequence $A \to B \to C$ is defined to be exact if the maps are proper and the natural map from the image of $A \to B$ to the kernel of $B \to C$ is an isomorphism. See, for example, Yoneda's paper "On Ext and Exact Sequences" or "Quasi-Abelian Categories and Sheaves" Jean-Pierre Schneiders.

A monomorphism is proper iff it is the kernel of some morphism, and dually for epimorphisms. If the category has all kernels and cokernels, then a monomorphism is proper iff it is the kernel of its cokernel, and dually for epimorphisms. So for a sequence $0 \to A \to B \to C \to 0$, if you require that the maps be proper, then the sequence is exact if and only if either (1) $A \to B$ is the kernel of $B \to C$ and $B \to C$ is an epimorphism, or (2) $B \to C$ is the cokernel of $A \to B$ and $A \to B$ is a monomorphism.