nLab
globular set

Idea

Globular sets are to simplicial sets as globes are to simplices.

Definition

A globular set is a presheaf on the globe category (described below), one of the geometric shapes for higher structures.

The presheaf definition is to be understood from the point of view of space and quantity: a globular set is a space characterized by the fact that and how it may be probed by mapping standard globes into it: the set $S_{n}$ assigned by a globular set to the standard $n$ -globe $[n]$ is the set of $n$ -globes in this space, hence the way of mapping a standard $n$ -globe into this spaces.

The globe category $G$ is the category whose objects are the integers and whose morphisms are generated from

$σ_{n} : [n] \to [n + 1]$ \sigma_n : [n] \to [n+1]
$τ_{n} : [n] \to [n + 1]$ \tau_n : [n] \to [n+1]
$ι_{n} : [n + 1] \to [n]$ \iota_n : [n+1] \to [n]

for all $n \in ℕ$ subject to the relations (dropping obvious subscripts)

$σ \circ σ = τ \circ σ$ \sigma\circ \sigma = \tau \circ \sigma
$σ \circ τ = τ \circ τ$ \sigma\circ \tau = \tau \circ \tau
$ι \circ σ = Id$ \iota \circ \sigma = \mathrm{Id}
$ι \circ τ = Id .$ \iota \circ \tau = \mathrm{Id} \,.

A globular object $S$ in a category $K$ is a functor $S : G^{op} \to K$ . In particular, for $K = Sets$ we say $S$ is a globular set.

For $n \in ℕ$ we write

$S_{n} : = S (n)$ S_n := S(n)
$s_{n} : = S (σ_{n}) : S_{n + 1} \to S_{n}$ s_n := S(\sigma_n) : S_{n+1} \to S_{n}
$t_{n} : = S (τ_{n}) : S_{n + 1} \to S_{n}$ t_n := S(\tau_n) : S_{n+1} \to S_{n}
$i_{n} : = S (ι_{n}) : S_{n} \to S_{n + 1}$ i_n := S(\iota_n) : S_{n} \to S_{n+1}

and call $S_{n}$ the collection of $n$ -cells; $s_{n}$ the $(n + 1)$ st source map and $t_{n}$ the
$(n + 1)$ st target map and $i_{n}$ the $n$ th identity assigning map.

The relations (dropping obvious subscripts)

$s \circ s = s \circ t$ s \circ s = s \circ t
$t \circ s = t \circ t$ t \circ s = t \circ t
$s \circ i = Id$ s \circ i = \mathrm{Id}
$t \circ i = Id$ t \circ i = \mathrm{Id}

are called the globular identities.

Marc: Perhaps it would be better, not to require reflexivity (i.e. the map $i$ ) in these definitions and use “reflexive globular set” if reflexivity is required? The way it is phrased now is in conflict with the terminology for directed graphs, where one uses “reflexive graphs” if these are meant, but allows graphs without distinguished loops.

A morphism of globular objects is a natural transformation of the corresponding functors. For the resulting category of globular objects in $K$ we write

GlobularObjects (K) : = K^{G^{op}}

Notation for composite globular maps

The globular identities ensure that

two sequences of boundary maps

$f_{n} \circ \dots \circ f_{n + m - 1} \circ f_{n + m} : S_{n + m + 1} \to S_{n}$ f_n \circ \cdots \circ f_{n+m-1} \circ f_{n+m} : S_{n+m+1} \to S_n

with $n, m \in ℕ$ and for $f_{k}, \in {s_{k}, t_{k}}$ are equal if and only if their last term $f_{n}$ coincides;

for all $n, m \in ℕ$ we have

s_{n} \dots s_{n + 1} \circ \dots \circ s_{n + m} \circ i_{n + m} \circ \dots \circ i_{n + 1} \circ i_{n} = Id

t_{n} \dots t_{n + 1} \circ \dots \circ t_{n + m} \circ i_{n + m} \circ \dots \circ i_{n + 1} \circ i_{n} = Id .

We therefore write

s_{n}, t_{n} : S_{n + m + 1} \to S_{n}

i_{n} : S_{n} \to S_{n + m + 1}

with $i_{n}, s_{n}, t_{m}$ the sequence of $m$ consecutive identity-assigning, source or target maps, respectively.

Examples

A globular set concentrated in degree 0 is just a set. A globular set concentrated in degrees 0 and 1 is a directed graph. See also directed n-graph.
The globular $n$ -globe $G_{n}$ is the globular set represented by $n$ , i.e. $G_{n} (-) : = {Hom}_{G} (-, n)$ .

Remarks

Globular sets are also referred to as $ω$ -graphs.
globular sets are based on one of the three major geometric shapes for higher structures.