Spahn mapping simplex (changes)

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In the theory of ~~cartesian~~ ~~fibrations~~ of ~~simplicial~~ ~~sets~~ ~~cartesian~~ ~~fibrations~~ ~~$X\to \Delta^n$~~ cartesian fibration s ~~over~~ of a simplicial ~~simplex~~ sets ~~play~~ cartesian an fibrations ~~important~~ ~~role~~ ~~since~~ an ~~arbitrary~~ ~~morphism~~ $X \to S Δ^{n}$ X\to S \Delta^n is over a ~~cartesian~~ simplex ~~fibration~~ play ~~iff~~ an important role since an arbitrary morphism $X \times_{S} \to X S$ ~~X\times_S~~ X\to X S is a cartesian fibration iff for all $n$ , $X\times_S \Delta^n\to \Delta^n$ is a cartesian fibration.

~~$X\to \Delta^n$~~ A cartesian fibration ~~is by the~~ $X\to \Delta^n$ ~~$(\infty,1)$~~ is by the ~~-Grothendieck construction equivalently a functor~~ $(\infty,1)$ ~~$\Delta^n\to (\infty,1)Cat$~~ -Grothendieck construction equivalently a functor ~~; i.e. a composable sequence of~~ $\Delta^n\to (\infty,1)Cat$ ~~$(\infty,1)$~~ ; i.e. a composable sequence of ~~-categories and functors~~ $(\infty,1)$ ~~$\phi:A^0\leftarrow\dots\leftarrow A^n$~~ -categories and functors $\phi:A^0\leftarrow\dots\leftarrow A^n$ .

~~The mapping simplex $M(\phi)$ of $\phi$ is defined by:~~

Definition

The mapping simplex $M(\phi)$ of $\phi$ is defined by:

For a nonempty finite finite linear order $L$ with greatest element $j$ , a map $\Delta^L\to M(\phi)$ consists of a order preserving map $f:L\to [n]$ and a morphism $\sigma:\Delta^L\to A^{f(j)}$ .
Given two such linear orders $L$ and $L^\prime$ with greatest elements $j$ resp. $j^\prime$ there is a natural map $M(\phi)(\Delta^{L^\prime})\to M(\phi)(\Delta^{L})$ sending $(f,\sigma)$ to $(f\circ p, e\circ \sigma)$ , where $e:A^{f(j^\prime)}\to A^{f(p(j))}$ is obtained by $\phi$ .

There is a natural map $h:M(\phi)\to \Delta^n$ (take $J=m$ , then the Yoneda lemma gives a map $\Delta^m\to \Delta^n$ ).

An edge $e$ of $M(\phi)$ is defined by a pair of integers $0\le i\le j\le n$ and an edge $e^\prime\in A^j$ . $M(\phi)$ becomes a marked simplicial set $(M(\phi), E)$ by marking those edges for which $e^\prime$ is degenerated.

For a nonempty finite finite linear order $L$ with greatest element $j$ , a map $\Delta^L\to M(\phi)$ consists of a order preserving map $f:L\to [n]$ and a morphism $\sigma^L\to A^{f(j)}$ .

Given two such linear orders $L$ and $L^\prime$ with greatest elements $j$ resp. $j^\prime$ there is a natural map $M(\phi)(\Delta^{L^\prime})\to M(\phi)(\Delta^{L})$ sending $(f,\sigma)$ to $(f\circ p, e\circ \sigma)$ , where $e:A^{f(j^\prime)}\to A^{f(p(j))}$ is obtained by $\phi$ .

Definition

Let $p:X\to \Delta^n$ be a cartesian fibration, let $\phi:A^0\leftarrow\dots\leftarrow A^n$ be a composable sequence of $(\infty,1)$ -categories and functors. Then A map $q:M(\phi)\to X$ is called a quasi-equivalence if it satisfies:

(1) The map $h$ commutes with $p$ and $q$ .

(2) $q$ sends marked edges of $M(\phi)$ to $p$ -cartesian ones.

(3) For every $0\le i\le n$ , the induced map $A^i\to p^{-1}\{ i \}$ is a categorical equivalence?.

Proposition

Let $p:X\to \Delta^n$ be a cartesian fibration.

(1) There exists a composable sequence of $(\infty,1)$ -categories and functors $\phi:A^0\leftarrow\dots\leftarrow A^n$ and a quasi-equivalence $q:M(\phi)\to X$ .

(2) If $\phi:A^0\leftarrow\dots\leftarrow A^n$ is a composable sequence and $q:M(\phi)\to X$ a quasi-equivalence. Then for any map $T\to \Delta^n$ , the induced map

M(\phi)\times_{\Delta^n}T\to X\times_{\Delta^n}T

is a categorical equivalence?.

Reference

Higher Topos Theory section 3.2.2.

Last revised on February 6, 2013 at 00:34:08. See the history of this page for a list of all contributions to it.

Spahn mapping simplex (changes)

Definition

Definition

Proposition

Related topics

Reference