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    • CommentRowNumber1.
    • CommentAuthorMike Shulman
    • CommentTimeMar 20th 2012

    Last June, Eduardo wrote at twisted arrow category:

    you could view then morphisms from ff to gg as factorizations of gg through ff; this is in fact a good way of getting the arrows directions above right.

    Eduardo, if you are reading this, or anyone else: can you explain further how this is supposed to help get the arrows’ directions right? Why should an arrow from ff to gg be a factorization of gg through ff rather than a factorization of ff through gg?

    Is there a sense other than convention in which this direction of the arrows (as opposed to the opposite one, defining the category Tw(A) opTw(A)^{op}) is the “correct” one? Is this the universally used convention?

    • CommentRowNumber2.
    • CommentAuthorTim_Porter
    • CommentTimeMar 20th 2012
    • (edited Mar 20th 2012)

    I always think that the terminology ‘factorisation of ff through gg’ has a sense that you start with ff and end up with gg. (That suggests a direction for the arrow from ff to gg.) This is a bit like a subdivision; you subdivide ff into three bits the middle one of which is gg. The other way is like a composition. I think that Baues and Wirshing adopted the wrong convention for their terminology!

    By the way Leech used this construction in his cohomology of monoids and Wells then worked with it for cohomology of categories before Baues and Wirsching came along. (I have added in the references into Baues-Wirsching cohomology. (Wells’ paper is very good. A pity it was not published.)

    • CommentRowNumber3.
    • CommentAuthoreparejatobes
    • CommentTimeMar 20th 2012

    For me, it does help in the form of Fact(C)=Tw(C) opFact(C) = Tw(C)^{op}; I should have explained this bit.

    Concerning directions, the main reason I see for Tw(C)Tw(C) as defined is that it is what you get from (*/hom C)(\ast / hom_C); for factorizations, it looks fairly obvious to me that the more rational choice is Fact(C)=Tw(C) opFact(C) = Tw(C)^{op}

    • CommentRowNumber4.
    • CommentAuthorMike Shulman
    • CommentTimeMar 20th 2012

    Eduardo, are you just saying that “morphisms from ff to gg are factorizations of gg through ff” helps you remember that the two arrows between ff and gg go in different directions, not which particular directions they go in?

    • CommentRowNumber5.
    • CommentAuthoreparejatobes
    • CommentTimeMar 21st 2012

    Mike #4:

    was in a hurry yesterday, I will try to expand a bit on this:

    First, there’s (at least for me) an obvious notion of Fact(C)Fact(C), where we want to have

    • objects arrows in CC
    • morphisms factorizations of one arrow through the other.

    Now, to match language usage (“ff factorizes through gg”), the direction of the morphisms should be

    (a,b):fg(a,b) \colon f \to g if f=bgaf = b g a

    Let’s call this category Fact(C)Fact(C). Sadly, according to Tim #2 it looks like the term “category of factorizations” has been used to refer to Fact(C) opFact(C)^{op}; anyway, I’ll stick for Fact(C)Fact(C) as defined for what follows.

    Now, twisted arrow categories. For me, the definition is just tw(C)=*/hom Ctw(C) = \ast / hom_C; but to get an explicit description, it is easier for me to just remember tw(C)=Fact(C) optw(C) = Fact(C)^{op}. This is essentially the content of “morphisms from f to g are factorizations of g through f”.

    Lastly, about whether we should have tw(C)=Fact(C) optw(C) = Fact(C)^{op} or tw(C)=Fact(C)tw(C) = Fact(C). I think that we should have tw(C)=Fact(C) optw(C) = Fact(C)^{op}, because

    1. tw(C)=*/hom Ctw(C) = \ast / hom_C
    2. In the Set\mathbf{Set} case, ends reduce to limits with shape tw(C)tw(C), while _co_ends reduce to colimits over tw(C) optw(C)^{op}
    3. Making tw(C)tw(C) a functor in Cat\mathbf{Cat}, ff is a unique lifting of factorizations functor iff tw(f)tw(f) is a discrete fibration
    4. it has been consistently defined as such in the past, in all of the sources I’ve seen
    • CommentRowNumber6.
    • CommentAuthorMike Shulman
    • CommentTimeMar 21st 2012

    Okay, thanks! I find your reason #4 the most compelling one.

    • CommentRowNumber7.
    • CommentAuthorDavid_Corfield
    • CommentTimeJul 7th 2014

    Mike’s post about his new papers took me to twisted arrow category and then to Baues-Wirsching cohomology, neither of which I’d noticed before. Both seem strangely unlinked to the rest of nLab.