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1. • CommentRowNumber1.
   • CommentAuthorMirco Richter
   • CommentTimeDec 4th 2014
   • (edited Dec 4th 2014)
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   Author: Mirco Richter
   Format: MarkdownItexReading through the construction of the generalized universal bundle in the section [[category of fibrant objects]] if have a problem with the existence. Accordng to the definition, In a category of fibrant objects it is not assumed that every pullback exists, but only those of fibrations. But then given a morphism $f: C \to B$ in a category of fibrant objects, the generalized universal bundles is defined by a pullback diagram as in Definition 3 of [[category of fibrant objects]]. Is this an ordinary (not homotopy) pullback? Then I would say, this does not necessarily exist, since $f$ is not assumed to be a fibration. Then concerning Definition (computing the homotopy fiber in terms of certain pullbacks) again, those pullbacks in the limit do not necessarily exist, do they? Because the proof of Lemma 10 requires the existence of pullbacks, but in a category of fibered objects pullbacks need only exist for fibrations. So if in the proof $v: B \to C$ or $u: A \to C$ are not fibrations, the construction does not work, I think. Am I seeing that wrong? And by the way, the link to the book of Kenneth S. Brown gives an empty pdf on my computer. A working link with open access is here: http://www.ams.org/journals/tran/1973-186-00/S0002-9947-1973-0341469-9/S0002-9947-1973-0341469-9.pdf

   Reading through the construction of the generalized universal bundle in the section category of fibrant objects if have a problem with the existence.

   Accordng to the definition, In a category of fibrant objects it is not assumed that every pullback exists, but only those of fibrations. But then given a morphism $f: C \to B$ in a category of fibrant objects, the generalized universal bundles is defined by a pullback diagram as in Definition 3 of category of fibrant objects.

   Is this an ordinary (not homotopy) pullback? Then I would say, this does not necessarily exist, since $f$ is not assumed to be a fibration.

   Then concerning Definition (computing the homotopy fiber in terms of certain pullbacks) again, those pullbacks in the limit do not necessarily exist, do they? Because the proof of Lemma 10 requires the existence of pullbacks, but in a category of fibered objects pullbacks need only exist for fibrations. So if in the proof $v: B \to C$ or $u: A \to C$ are not fibrations, the construction does not work, I think.

   Am I seeing that wrong?

   And by the way, the link to the book of Kenneth S. Brown gives an empty pdf on my computer.

   A working link with open access is here: http://www.ams.org/journals/tran/1973-186-00/S0002-9947-1973-0341469-9/S0002-9947-1973-0341469-9.pdf

2. • CommentRowNumber2.
   • CommentAuthorMirco Richter
   • CommentTimeDec 4th 2014
   • PermaLink
   Author: Mirco Richter
   Format: MarkdownItexReading through the book of K.S. Brown the question remains, how the definition in the book is equivalent to the definition in [[category of fibrant objects]] ?

   Reading through the book of K.S. Brown the question remains, how the definition in the book is equivalent to the definition in category of fibrant objects ?

3. • CommentRowNumber3.
   • CommentAuthorTim_Porter
   • CommentTimeDec 4th 2014
   • (edited Dec 4th 2014)
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   Author: Tim_Porter
   Format: MarkdownItexThat entry if kicking! On Firefox I get error messages: XML Parsing Error: no element found Location: http://ncatlab.org/nlab/show/category+of+fibrant+objects Line Number 1331, Column 1585: On Safari some of the page loads but the end does not, so presumably there is something wrong after that. (EDIT: the problem has cleared.)

   That entry if kicking! On Firefox I get error messages:

   XML Parsing Error: no element found Location: http://ncatlab.org/nlab/show/category+of+fibrant+objects Line Number 1331, Column 1585:

   On Safari some of the page loads but the end does not, so presumably there is something wrong after that.

   (EDIT: the problem has cleared.)

4. • CommentRowNumber4.
   • CommentAuthorMirco Richter
   • CommentTimeDec 4th 2014
   • PermaLink
   Author: Mirco Richter
   Format: MarkdownItexOn Chromium, I face some math typesetting errors for days all over the nLab, too.

   On Chromium, I face some math typesetting errors for days all over the nLab, too.

5. • CommentRowNumber5.
   • CommentAuthorTim_Porter
   • CommentTimeDec 4th 2014
   • (edited Dec 4th 2014)
   • PermaLink
   Author: Tim_Porter
   Format: MarkdownItexLoading it on Safari is patchy. I tried shortly after my previous message and it loaded. (The pdf file seems dead as you said, Mirco.) Has there been an update of some of the Mathml related programs?

   Loading it on Safari is patchy. I tried shortly after my previous message and it loaded. (The pdf file seems dead as you said, Mirco.)

   Has there been an update of some of the Mathml related programs?

6. • CommentRowNumber6.
   • CommentAuthorMirco Richter
   • CommentTimeDec 4th 2014
   • (edited Dec 4th 2014)
   • PermaLink
   Author: Mirco Richter
   Format: MarkdownItexYes but the new link I gave above http://www.ams.org/journals/tran/1973-186-00/S0002-9947-1973-0341469-9/ or directly http://www.ams.org/journals/tran/1973-186-00/S0002-9947-1973-0341469-9/S0002-9947-1973-0341469-9.pdf works for me. Anyway, my problem boils down to the following: 1.) In the nLab entry the axiom says: finite products and pullbacks of fibrations exists. 2.) In the paper of brown ther axiom (c) saying, that for a diagram $A \xrightarrow{u} C\xleftarrow{v} B$ where $v$ is a fibration, the pullback $A \times_{C} B$ exist, and the projection $p: A \times_{C} B \to A$ is a fibration. So what I don't see is how the nLab def is equivalent to that of Brown, I.e how we can follow axiom (C) from the nLab definition. Maybe this is obvious, but I would say it is worth, at least, to mention how this works. Axiom (C) is of central importance for the computation of the generalized universal bundles and the homotopy fiber product as in the entry.

   Yes but the new link I gave above

   http://www.ams.org/journals/tran/1973-186-00/S0002-9947-1973-0341469-9/

   or directly http://www.ams.org/journals/tran/1973-186-00/S0002-9947-1973-0341469-9/S0002-9947-1973-0341469-9.pdf

   works for me.

   Anyway, my problem boils down to the following:

   1.) In the nLab entry the axiom says: finite products and pullbacks of fibrations exists.

   2.) In the paper of brown ther axiom (c) saying, that for a diagram

   $A \xrightarrow{u} C\xleftarrow{v} B$ where $v$ is a fibration, the pullback $A \times_{C} B$ exist, and the projection $p: A \times_{C} B \to A$ is a fibration.

   So what I don’t see is how the nLab def is equivalent to that of Brown, I.e how we can follow axiom (C) from the nLab definition. Maybe this is obvious, but I would say it is worth, at least, to mention how this works. Axiom (C) is of central importance for the computation of the generalized universal bundles and the homotopy fiber product as in the entry.

7. • CommentRowNumber7.
   • CommentAuthorMirco Richter
   • CommentTimeDec 4th 2014
   • (edited Dec 4th 2014)
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   Author: Mirco Richter
   Format: MarkdownItexOr is it just that "pullbacks of fibrations exist" just means exactly axiom (C), that is "pullbacks of fibrations exist" means only one arrow in the index diagram needs to be a fibation? Ok I'm not an English native, but then "pullbacks of fibrations exist" should be called "pullbacks of a fibration exist" or something. Don't? For me the first one sounds like "the pullback exists, if BOTH arrows are fibrations."

   Or is it just that “pullbacks of fibrations exist” just means exactly axiom (C), that is “pullbacks of fibrations exist” means only one arrow in the index diagram needs to be a fibation?

   Ok I’m not an English native, but then “pullbacks of fibrations exist” should be called “pullbacks of a fibration exist” or something. Don’t? For me the first one sounds like “the pullback exists, if BOTH arrows are fibrations.”

8. • CommentRowNumber8.
   • CommentAuthorTim_Porter
   • CommentTimeDec 4th 2014
   • PermaLink
   Author: Tim_Porter
   Format: MarkdownItexI would read it as 'a pullback of any fibration along a morphism to its base exists'. I think the point is that the traditional / classical view of 'change of base' is influencing the wording in the original paper. The sense you had read was perhaps the result of the many years from KSB's article to the present.

   I would read it as ’a pullback of any fibration along a morphism to its base exists’. I think the point is that the traditional / classical view of ’change of base’ is influencing the wording in the original paper. The sense you had read was perhaps the result of the many years from KSB’s article to the present.

9. • CommentRowNumber9.
   • CommentAuthorMirco Richter
   • CommentTimeDec 4th 2014
   • PermaLink
   Author: Mirco Richter
   Format: MarkdownItexNow it makes sense. However not Browns definition sounds ambiguous. His 'axiom (C)' is very clear, but the one in the nLab entry leaves room for misinterpretation.

   Now it makes sense. However not Browns definition sounds ambiguous. His ’axiom (C)’ is very clear, but the one in the nLab entry leaves room for misinterpretation.

10. • CommentRowNumber10.
    • CommentAuthorUrs
    • CommentTimeDec 4th 2014
    • PermaLink
    Author: Urs
    Format: MarkdownItexYes, as Tim says, "pullback of XYZ" means along any morphism. Pullback is something that one does to one thing and along a base morphism. Otherwise, when both morphisms are regarded on the same footing, then one rather speaks of their fiber product. But to clarify I have added to the entry "(along any morphism)". Please fix the link to the pdf where you see the need!

    Yes, as Tim says, “pullback of XYZ” means along any morphism. Pullback is something that one does to one thing and along a base morphism. Otherwise, when both morphisms are regarded on the same footing, then one rather speaks of their fiber product. But to clarify I have added to the entry “(along any morphism)”.

    Please fix the link to the pdf where you see the need!

11. • CommentRowNumber11.
    • CommentAuthorMirco Richter
    • CommentTimeDec 4th 2014
    • PermaLink
    Author: Mirco Richter
    Format: MarkdownItexAll right then.

    All right then.

12. • CommentRowNumber12.
    • CommentAuthoradeelkh
    • CommentTimeDec 4th 2014
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    Author: adeelkh
    Format: MarkdownItexI would propose condensing the first three axioms * $C$ has [[finite products]] and pullbacks of fibrations (along all morphisms); * $C$ has a [[terminal object]] ${*}$; * fibrations are preserved under [[pullback]]; into * $C$ has [[finite products]], and in particular a [[terminal object]] ${*}$; * the [[pullback]] of a fibration along an arbitrary morphism exists, and is again a fibration;

    I would propose condensing the first three axioms

    • $C$ has finite products and pullbacks of fibrations (along all morphisms);

    • $C$ has a terminal object ${*}$;

    • fibrations are preserved under pullback;

    into

    • $C$ has finite products, and in particular a terminal object ${*}$;

    • the pullback of a fibration along an arbitrary morphism exists, and is again a fibration;

13. • CommentRowNumber13.
    • CommentAuthorUrs
    • CommentTimeDec 4th 2014
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    Author: Urs
    Format: MarkdownItexFine with me. Please feel invited to polish the entry.

    Fine with me. Please feel invited to polish the entry.

14. • CommentRowNumber14.
    • CommentAuthoradeelkh
    • CommentTimeDec 4th 2014
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    Author: adeelkh
    Format: MarkdownItexOK, done.

    OK, done.