Segal maps, named after Graeme Segal, appear in the definition of the *Segal conditions* on a simplicial object.

In the context of higher category theory they were used by Charles Rezk to define Segal categories and complete Segal spaces.

Let $X$ be a bisimplicial set. Assume for simplicity that $X$ is fibrant with respect to the Reedy model structure on the functor category $[\Delta^{op}, SSet]$. The **$n$-th Segal map** of $X$ is the canonical morphism of simplicial sets

$X_n \to (X_1)^{\times_{X_0} (n)} = X_1 \times_{X_0} \cdots \times_{X_0} X_1.$

Here the right-hand side is the limit of the diagram

$X_1 \stackrel{d_1}{\to} X_0 \stackrel{d_0}{\leftarrow} X_1 \stackrel{d_1}{\to} \cdots \stackrel{d_1}{\to} X_0 \stackrel{d_0}{\leftarrow} X_1$

where there are $n$ copies of $X_1$.

More explicitly, this morphism is induced by the morphisms $a_i: X_n \to X_1$ ($0 \le i \le n-1$), which are induced by the morphisms $\alpha^i: [1] \to [n]$ in $\Delta$, the simplex category, which map $0 \mapsto i$ and $1 \mapsto i+1$.

If $X$ is not Reedy fibrant, then one must replace the limit above with a homotopy limit.

- Julie Bergner,
*Three models for the homotopy theory of homotopy theories*, Topology 46 (2007), 397-436, arXiv:math/0504334.

Last revised on June 9, 2021 at 21:24:21. See the history of this page for a list of all contributions to it.