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nLab > Latest Changes: permutation representation

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- CommentRowNumber101.
- CommentAuthorUrs
- CommentTimeOct 21st 2019
- (edited Oct 21st 2019)
- PermaLink
Author: Urs
Format: MarkdownItexadded a graphics ([here](https://ncatlab.org/nlab/show/permutation+representation#ComparisonMapFromBurnsideRingToRepresentationRing)) illustarting the map from a) unstable equivariant Cohomotopy of representation spheres to b) the Burnside ring to c) the representation ring Now that I have done it I see that I should have made the labels "$G$" be explicitly "$\mathbb{Z}_4$". Will fix later. <a href="https://ncatlab.org/nlab/revision/diff/permutation+representation/41">diff</a>, <a href="https://ncatlab.org/nlab/revision/permutation+representation/41">v41</a>, <a href="https://ncatlab.org/nlab/show/permutation+representation">current</a>

added a graphics (here) illustarting the map from a) unstable equivariant Cohomotopy of representation spheres to b) the Burnside ring to c) the representation ring

Now that I have done it I see that I should have made the labels “ $G$ ” be explicitly “ $\mathbb{Z}_4$ ”. Will fix later.

diff, v41, current
- CommentRowNumber102.
- CommentAuthorUrs
- CommentTimeJun 3rd 2020
- (edited Jun 3rd 2020)
- PermaLink
Author: Urs
Format: MarkdownItexadded this historical pointer (dug out by David C. [in](https://nforum.ncatlab.org/discussion/7282/burnside-ring/?Focus=85074#Comment_85074) another thread) where the term "representation group" is used to refer to a group equipped with a permutation representation: * [[William Burnside]], _On the Representation of a Group of Finite Order as a Permutation Group, and on the Composition of Permutation Groups_, Proceedings of the American Mathematical Society 1901 ([doi:10.1112/plms/s1-34.1.159](https://doi.org/10.1112/plms/s1-34.1.159)) <a href="https://ncatlab.org/nlab/revision/diff/permutation+representation/43">diff</a>, <a href="https://ncatlab.org/nlab/revision/permutation+representation/43">v43</a>, <a href="https://ncatlab.org/nlab/show/permutation+representation">current</a>
added this historical pointer (dug out by David C. in another thread) where the term “representation group” is used to refer to a group equipped with a permutation representation:
- William Burnside, On the Representation of a Group of Finite Order as a Permutation Group, and on the Composition of Permutation Groups, Proceedings of the American Mathematical Society 1901 (doi:10.1112/plms/s1-34.1.159)
diff, v43, current
- CommentRowNumber103.
- CommentAuthorUrs
- CommentTimeJun 3rd 2020
- PermaLink
Author: Urs
Format: MarkdownItexSorry, wrong spot. Actually Burnside means by "permutation group" what we now call a "$G$-set". Am moving the reference.

Sorry, wrong spot. Actually Burnside means by “permutation group” what we now call a “ $G$ -set”. Am moving the reference.
- CommentRowNumber104.
- CommentAuthorDavid_Corfield
- CommentTimeJun 15th 2021
- (edited Jun 15th 2021)
- PermaLink
Author: David_Corfield
Format: MarkdownItexI wonder if anything interesting happens if we shift from $G$ acting on sets to it acting on the finite $\infty$-groupoids treated in * [[Imma Gálvez-Carrillo]], [[Joachim Kock]], and [[Andrew Tonks]]. _Homotopy linear algebra_. Proc. Roy. Soc. Edinburgh Sect. A, 148(2):293–325, 2018 ([arXiv:1602.05082](https://arxiv.org/abs/1602.05082)) What plays the role of finite vector spaces there are the slices $\mathcal{F}/\alpha$, where $\mathcal{F}$ is the $(\infty, 1)$-category of finite $\infty$-groupoids. These slices are objects of $lin$, whose morphisms are derived from spans of finite $\infty$-groupoids, $\alpha \leftarrow \mu \to \beta$. There's a 'cardinality' map from $lin$ to $FinVect$. Wild speculation: perhaps virtual permutation reps in this setting could close the gap with virtual linear reps.
I wonder if anything interesting happens if we shift from $G$ acting on sets to it acting on the finite $\infty$ -groupoids treated in
- Imma Gálvez-Carrillo, Joachim Kock, and Andrew Tonks. Homotopy linear algebra. Proc. Roy. Soc. Edinburgh Sect. A, 148(2):293–325, 2018 (arXiv:1602.05082)
What plays the role of finite vector spaces there are the slices $\mathcal{F}/\alpha$ , where $\mathcal{F}$ is the $(\infty, 1)$ -category of finite $\infty$ -groupoids. These slices are objects of $lin$ , whose morphisms are derived from spans of finite $\infty$ -groupoids, $\alpha \leftarrow \mu \to \beta$ . There’s a ’cardinality’ map from $lin$ to $FinVect$ .

Wild speculation: perhaps virtual permutation reps in this setting could close the gap with virtual linear reps.
- CommentRowNumber105.
- CommentAuthorUrs
- CommentTimeJun 15th 2021
- PermaLink
Author: Urs
Format: MarkdownItexSpeaking of wild speculation, I keep wondering if it's just a coincidence that the 2-site for [[global equivariant homotopy theory]] -- namely the [[global orbit category]] -- is that of connected finite 1-groupoids (connected finite homotopy 1-types). This suggests that the $\infty$-site for globally "higher equivariant" homotopy theory is that of all finite $\infty$-groupoids. Moreover, the site for $G$-equivariant homotopy theory is the faithful slice of this site over the delooping groupoid of $G$, which suggests that the faithful slices $(\mathcal{F}/\alpha)^{faith}$ of finite $\infty$-groupoids over deloopings of finite $\infty$-groups $\alpha = B \mathcal{G}$ are the sites for higher $\mathcal{G}$-equivariant homotopy theory. These ingredients are not-so-vaguely reminiscent of Goodwillie calculus, which works over the opposite and pointed site of finite $\infty$-groupoids (e.g. [here](https://ncatlab.org/nlab/show/model+structure+for+excisive+functors#TheUnderlyingCategories)). Probably Goodwillie calculus is also a good thing to keep in mind when thinking of homotopy linear algebra.

Speaking of wild speculation, I keep wondering if it’s just a coincidence that the 2-site for global equivariant homotopy theory – namely the global orbit category – is that of connected finite 1-groupoids (connected finite homotopy 1-types). This suggests that the $\infty$ -site for globally “higher equivariant” homotopy theory is that of all finite $\infty$ -groupoids.

Moreover, the site for $G$ -equivariant homotopy theory is the faithful slice of this site over the delooping groupoid of $G$ , which suggests that the faithful slices $(\mathcal{F}/\alpha)^{faith}$ of finite $\infty$ -groupoids over deloopings of finite $\infty$ -groups $\alpha = B \mathcal{G}$ are the sites for higher $\mathcal{G}$ -equivariant homotopy theory.

These ingredients are not-so-vaguely reminiscent of Goodwillie calculus, which works over the opposite and pointed site of finite $\infty$ -groupoids (e.g. here).

Probably Goodwillie calculus is also a good thing to keep in mind when thinking of homotopy linear algebra.
- CommentRowNumber106.
- CommentAuthorDavid_Corfield
- CommentTimeJun 15th 2021
- PermaLink
Author: David_Corfield
Format: MarkdownItexHomotopy linear algebra certainly fits very neatly with polynomial and analytic functors in the non-Goodwillie sense, as in * [[David Gepner]], [[Rune Haugseng]], [[Joachim Kock]], _∞-Operads as Analytic Monads_, ([arXiv:1712.06469](https://arxiv.org/abs/1712.06469)). Is there an $\mathbb{F}_1$ view on finite $\infty$-groupoids? I see in the [notes](https://www.msri.org/workshops/689/schedules/18234/documents/2047/assets/20469) by Barwick, $\mathsf{Perf}_{\mathbb{C}}$ is > the $(\infty,1)$-category of perfect $H \mathbb{C}$-modules – that is, of $H \mathbb{C}$-modules with finitely many homotopy groups, all of which are finite-dimensional. $H \mathbb{F}_1$-modules would give us what? Chains of sets?
Homotopy linear algebra certainly fits very neatly with polynomial and analytic functors in the non-Goodwillie sense, as in
- David Gepner, Rune Haugseng, Joachim Kock, ∞-Operads as Analytic Monads, (arXiv:1712.06469).
Is there an $\mathbb{F}_1$ view on finite $\infty$ -groupoids? I see in the notes by Barwick, $\mathsf{Perf}_{\mathbb{C}}$ is

the $(\infty,1)$ -category of perfect $H \mathbb{C}$ -modules – that is, of $H \mathbb{C}$ -modules with finitely many homotopy groups, all of which are finite-dimensional.

$H \mathbb{F}_1$ -modules would give us what? Chains of sets?

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nLab > Latest Changes: permutation representation