nLab
globular set

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Globular sets

Idea

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

They are one of the major geometric shapes for higher structures: if they satisfy a globular Segal condition then they are equivalent to strict ω-categories.

Definition

Basic definition

Definition

The globe category 𝔾 is the category whose objects are the natural numbers, denoted here [n] and whose morphisms are generated from

σ n:[n][n+1]\sigma_n : [n] \to [n+1]
τ n:[n][n+1]\tau_n : [n] \to [n+1]

for all n subject to the relations (dropping obvious subscripts)

σσ=τσ\sigma\circ \sigma = \tau \circ \sigma
στ=ττ.\sigma\circ \tau = \tau \circ \tau \,.
Definition

A globular set, also called an ω-graph is a presheaf on 𝔾. The category of globular sets is the category of presheaves

gSetPSh(𝔾).gSet \coloneqq PSh(\mathbb{G}) \,.
Remark

This means that a globular set XgSet is given by a collection of sets {X n} n, called the sets of n-globes, equipped with functions

{s n,t n:X n+1X n} n\{s_n,t_n \colon X_{n+1} \to X_n\}_{n \in \mathbb{N}}

called the n-target and n-source maps (or similar), such that the globular identities hold: for all n

  • s ns n+1=s nt n+1

  • t ns n+1=t nt n+1.

Remark

The globular identities ensure that two sequences of boundary maps

f nf n+m1f n+m:S n+m+1S nf_n \circ \cdots \circ f_{n+m-1} \circ f_{n+m} : S_{n+m+1} \to S_n

with n,m and for f k,{s k,t k} are equal if and only if their last term f n coincides; for all n,m we have

s ns n+1s n+mi n+mi n+1i n=Ids_n \cdots s_{n+1} \circ \cdots \circ s_{n+m} \circ i_{n+m} \circ \cdots \circ i_{n+1} \circ i_n = \mathrm{Id}
t nt n+1t n+mi n+mi n+1i n=Id.t_n \cdots t_{n+1} \circ \cdots \circ t_{n+m} \circ i_{n+m} \circ \cdots \circ i_{n+1} \circ i_n = \mathrm{Id} \,.

For S a globular set we may therefore write unambigously

s n,t n:S n+m+1S ns_n, t_n : S_{n+m+1} \to S_n
i n:S nS n+m+1i_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.

Remark

The presheaf definition can 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.

More generally:

Definition

A globular object X in a category 𝒞 is a functor X:𝔾 op𝒞.

Reflexive globular sets

If to the globe category we add additional generating morphisms

ι n:[n+1][n]\iota_n : [n+1] \to [n]

satisfying the relations

ισ=Id\iota \circ \sigma = \mathrm{Id}
ιτ=Id\iota \circ \tau = \mathrm{Id}

we obtain the reflexive globe category, a presheaf on which is a reflexive globular set. In this case the morphism

i n:=S(ι n):S nS n+1i_n := S(\iota_n) : S_{n} \to S_{n+1}

is called the nth identity assigning map; it satisfies the globular identities:

si=Ids \circ i = \mathrm{Id}
ti=Idt \circ i = \mathrm{Id}

n-globular sets

A presheaf on the full subcategory of the globe category containing only the integers [0] through [n] is called an n-globular set or an n-graph or an n-graph. An n-globular set may be identified with an -globular set which is empty above dimension n.

Note that a 1-globular set is just a directed graph, and a 0-globular set is just a set.

Examples

References

The definition is reviewed around def. 1.4.5, p. 49 of

See also

  • Sjoerd Crans, On combinatorial models for higher dimensional homotopies (web)

Revised on November 29, 2012 15:21:15 by Urs Schreiber (82.169.65.155)
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