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1. • CommentRowNumber1.
   • CommentAuthorUrs
   • CommentTimeApr 24th 2010
   • (edited Jul 8th 2013)
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   Author: Urs
   Format: MarkdownItexstarted [[fiber integration]]

   started fiber integration

2. • CommentRowNumber2.
   • CommentAuthorUrs
   • CommentTimeApr 24th 2010
   • (edited Apr 24th 2010)
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   Author: Urs
   Format: MarkdownItexadded a few more details and a set of slides as a reference. The big question for me is: what is a more abstract way to think of that integration map $\int_F$ ? It looks a bit wild. There must be a way to say this more elegantly, I'd hope. Thursday I asked somebody who is expert on this stuff for a good reference on the general theory of fiber integration in generalized cohomology. He just shrugged :-).

   added a few more details and a set of slides as a reference.

   The big question for me is: what is a more abstract way to think of that integration map $\int_F$ ? It looks a bit wild. There must be a way to say this more elegantly, I’d hope.

   Thursday I asked somebody who is expert on this stuff for a good reference on the general theory of fiber integration in generalized cohomology. He just shrugged :-).

3. • CommentRowNumber3.
   • CommentAuthorzskoda
   • CommentTimeApr 24th 2010
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   Author: zskoda
   Format: MarkdownThis pushforward is either with compact supports or alike. I always emphasise proper pushforward in similar business, and is different from just pushforward. In algebraic geometry it is usually much more studied. References in algebraic topology I do not know but it is related to Spanier-Whitehead duality business and Thom spaces, so probably there is a good treatment in Rudyak's book, but have no time to check now.

   This pushforward is either with compact supports or alike. I always emphasise proper pushforward in similar business, and is different from just pushforward. In algebraic geometry it is usually much more studied. References in algebraic topology I do not know but it is related to Spanier-Whitehead duality business and Thom spaces, so probably there is a good treatment in Rudyak's book, but have no time to check now.

4. • CommentRowNumber4.
   • CommentAuthorUrs
   • CommentTimeApr 24th 2010
   • (edited Apr 24th 2010)
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   Author: Urs
   Format: MarkdownItexI found this reference here <a href="http://arxiv.org/PS_cache/arxiv/pdf/0711/0711.0540v1.pdf">Cohen-Klein: Umkehr maps</a> which seems to go a long way towards the goal of reducing the fiber integration formula to abstract nonsense. Effectively what they say is that one should look at functors $Top^{op} \to Spectra$, represented by spectra by sending a spectrum not just to its cohomology on each given space, but to its _mapping spectrum_ . Then notably the construction of the Thom space of the (stable) normal bundle of some $P$ -- crucial in the fiber integration business -- is just, they say, the mapping spectrum $hom(P, S^0)$, where $S^0$ is the sphere spectrum (page 5). They discuss fiber integration in deRham cohomology in this language (page 6).

   I found this reference here

   Cohen-Klein: Umkehr maps

   which seems to go a long way towards the goal of reducing the fiber integration formula to abstract nonsense.

   Effectively what they say is that one should look at functors $Top^{op} \to Spectra$, represented by spectra by sending a spectrum not just to its cohomology on each given space, but to its mapping spectrum . Then notably the construction of the Thom space of the (stable) normal bundle of some $P$ – crucial in the fiber integration business – is just, they say, the mapping spectrum $hom(P, S^0)$, where $S^0$ is the sphere spectrum (page 5).

   They discuss fiber integration in deRham cohomology in this language (page 6).

5. • CommentRowNumber5.
   • CommentAuthorzskoda
   • CommentTimeApr 24th 2010
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   Author: zskoda
   Format: MarkdownSo what is "Thom spectrum" ?

   So what is "Thom spectrum" ?

6. • CommentRowNumber6.
   • CommentAuthorUrs
   • CommentTimeApr 24th 2010
   • (edited Apr 24th 2010)
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   Author: Urs
   Format: MarkdownItex> So what is "Thom spectrum" ? Its the spectrum given by the sequence of Thom spaces $M SO(n)$ associated to the associated bundle of the universal $SO(n)$-bundle for all $n$. Have to run now. More later.

   So what is “Thom spectrum” ?

   Its the spectrum given by the sequence of Thom spaces $M SO(n)$ associated to the associated bundle of the universal $SO(n)$-bundle for all $n$.

   Have to run now. More later.

7. • CommentRowNumber7.
   • CommentAuthorzskoda
   • CommentTimeApr 24th 2010
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   Author: zskoda
   Format: MarkdownBut this is the classical case, isn't there a generalized version ?

   But this is the classical case, isn't there a generalized version ?

8. • CommentRowNumber8.
   • CommentAuthordomenico_fiorenza
   • CommentTimeApr 24th 2010
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   Author: domenico_fiorenza
   Format: MarkdownItexI'm not completely convinced of the abstract nonense approach in Cohen-Klein. in a sense, it can be summarized by saying that a wrong way map is induced by a right way map and a duality. and this duality explicitly calls in a notion of sphere bundle associated to a virtual vector bundle, so that in many ways this abstract nonsense is much less abstract than it would like to be. (I have a suspect this is the same comment as Zoran's, only written in different words)

   I’m not completely convinced of the abstract nonense approach in Cohen-Klein. in a sense, it can be summarized by saying that a wrong way map is induced by a right way map and a duality. and this duality explicitly calls in a notion of sphere bundle associated to a virtual vector bundle, so that in many ways this abstract nonsense is much less abstract than it would like to be.

   (I have a suspect this is the same comment as Zoran’s, only written in different words)

9. • CommentRowNumber9.
   • CommentAuthordomenico_fiorenza
   • CommentTimeApr 24th 2010
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   Author: domenico_fiorenza
   Format: MarkdownItexsomething closely related, and which we seem to be missing an nPOV on (and an nLab entry) is Leray-Serre spectral sequence of a fibration $F\to E\to B$. in the particular case of a sphere bundle on a connected base, the $k$-th differential in the spectral sequence $d_k:\mathbb{Z}=H^0(B,H^k(S^k,\mathbb{Z})\to H^{k+1}(B,H^0(S^k,\mathbb{Z})$ determines a distinguished element $e:=d_k(1)$ in $H^{k+1}(B,\mathbb{Z})$, the Euler class of the sphere bundle, and integration along the fibres fits into an exact triangle whose other two edges are the pullback $H^*(B,\mathbb{Z})\to H^*(E,\mathbb{Z})$ and the cup product with the Euler class $H^*(E,\mathbb{Z})\to H^{*+k+1}(E,\mathbb{Z})$.

   something closely related, and which we seem to be missing an nPOV on (and an nLab entry) is Leray-Serre spectral sequence of a fibration $F\to E\to B$.

   in the particular case of a sphere bundle on a connected base, the $k$-th differential in the spectral sequence $d_k:\mathbb{Z}=H^0(B,H^k(S^k,\mathbb{Z})\to H^{k+1}(B,H^0(S^k,\mathbb{Z})$ determines a distinguished element $e:=d_k(1)$ in $H^{k+1}(B,\mathbb{Z})$, the Euler class of the sphere bundle, and integration along the fibres fits into an exact triangle whose other two edges are the pullback $H^*(B,\mathbb{Z})\to H^*(E,\mathbb{Z})$ and the cup product with the Euler class $H^*(E,\mathbb{Z})\to H^{*+k+1}(E,\mathbb{Z})$.

10. • CommentRowNumber10.
    • CommentAuthordomenico_fiorenza
    • CommentTimeApr 25th 2010
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    Author: domenico_fiorenza
    Format: MarkdownItexjust a toy exaple for today. assume we want to compute the cohomology group $H^n(X\times S^k,A)$ for some abelian group $A$. if $\mathbf{H}=\mathbf{Top}$ is the oo-topos of nice topological spaces, then what we want to determine is $\pi_0\mathbf{H}(X\times S^k,\mathcal{B}^n A)=\pi_0\mathbf{H}(X,\mathbf{H}(S^k,\mathcal{B}^n A))$. so we are interested into maps with target $\mathbf{H}(S^k,\mathcal{B}^n A)$. as we have seen in comment 119 <a href="http://www.math.ntnu.no/~stacey/Vanilla/nForum/comments.php?DiscussionID=1046">here</a>, this space has at most two nontrivial homotopy groups (exactly one if $n\lt k$ and exactly two if $n\geq k$): $\pi_n\mathbf{H}(S^k,\mathcal{B}^n A)=A$ and $\pi_{n-k}\mathbf{H}(S^k,\mathcal{B}^n A)=A$. so, if $n\lt k$, then $\mathbf{H}(S^k,\mathcal{B}^n A)\simeq \mathcal{B}^n A$, so we recover that $H^n(X\times S^k,A)=H^n(X,A)$ for $n\lt k$. in the $n\leq k$ situation, the Postnikov tower of $\mathbf{H}(S^k,\mathcal{B}^n A)$ involves a $\mathcal{B}^n A$ and a $\mathcal{B}^{n-k} A$, and we recover that $H^n(X\times S^k,A)$ has a contribution from $H^n(X,A)$ and one from $H^{n-k}(X,A)$. (I have to expand this, but have to run now..)

    just a toy exaple for today. assume we want to compute the cohomology group $H^n(X\times S^k,A)$ for some abelian group $A$. if $\mathbf{H}=\mathbf{Top}$ is the oo-topos of nice topological spaces, then what we want to determine is $\pi_0\mathbf{H}(X\times S^k,\mathcal{B}^n A)=\pi_0\mathbf{H}(X,\mathbf{H}(S^k,\mathcal{B}^n A))$. so we are interested into maps with target $\mathbf{H}(S^k,\mathcal{B}^n A)$. as we have seen in comment 119 here, this space has at most two nontrivial homotopy groups (exactly one if $n\lt k$ and exactly two if $n\geq k$): $\pi_n\mathbf{H}(S^k,\mathcal{B}^n A)=A$ and $\pi_{n-k}\mathbf{H}(S^k,\mathcal{B}^n A)=A$. so, if $n\lt k$, then $\mathbf{H}(S^k,\mathcal{B}^n A)\simeq \mathcal{B}^n A$, so we recover that $H^n(X\times S^k,A)=H^n(X,A)$ for $n\lt k$. in the $n\leq k$ situation, the Postnikov tower of $\mathbf{H}(S^k,\mathcal{B}^n A)$ involves a $\mathcal{B}^n A$ and a $\mathcal{B}^{n-k} A$, and we recover that $H^n(X\times S^k,A)$ has a contribution from $H^n(X,A)$ and one from $H^{n-k}(X,A)$.

    (I have to expand this, but have to run now..)

11. • CommentRowNumber11.
    • CommentAuthorUrs
    • CommentTimeJul 8th 2013
    • (edited Jul 8th 2013)
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    Author: Urs
    Format: MarkdownItexadded a section * _[push-forward in generalized cohomology -- Examples -- In twisted K-theory](http://ncatlab.org/nlab/show/fiber+integration#KKPushforwardAlongGeneralMap)_ in terms of pushing by dual morphisms in KK-theory.

    added a section

    • push-forward in generalized cohomology – Examples – In twisted K-theory

    in terms of pushing by dual morphisms in KK-theory.

12. • CommentRowNumber12.
    • CommentAuthorDmitri Pavlov
    • CommentTimeJul 4th 2019
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    Author: Dmitri Pavlov
    Format: MarkdownItexAdded a redirect for "fiberwise integral". <a href="https://ncatlab.org/nlab/revision/diff/fiber+integration/41">diff</a>, <a href="https://ncatlab.org/nlab/revision/fiber+integration/41">v41</a>, <a href="https://ncatlab.org/nlab/show/fiber+integration">current</a>

    Added a redirect for “fiberwise integral”.

    diff, v41, current

13. • CommentRowNumber13.
    • CommentAuthorDmitri Pavlov
    • CommentTimeFeb 12th 2020
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    Author: Dmitri Pavlov
    Format: MarkdownItexAdded a description of the ordinary fiberwise integration of differential forms. <a href="https://ncatlab.org/nlab/revision/diff/fiber+integration/43">diff</a>, <a href="https://ncatlab.org/nlab/revision/fiber+integration/43">v43</a>, <a href="https://ncatlab.org/nlab/show/fiber+integration">current</a>

    Added a description of the ordinary fiberwise integration of differential forms.

    diff, v43, current