(-1)-groupoid

- homotopy hypothesis-theorem
- delooping hypothesis-theorem
- periodic table
- stabilization hypothesis-theorem
- exactness hypothesis
- holographic principle

- (n,r)-category
- Theta-space
- ∞-category/∞-category
- (∞,n)-category
- (∞,2)-category
- (∞,1)-category
- (∞,0)-category/∞-groupoid
- n-category = (n,n)-category
- 2-category, (2,1)-category
- 1-category
- 0-category
- (?1)-category?
- (?2)-category?

- n-poset = (n-1,n)-category
- n-groupoid = (n,0)-category

- categorification/decategorification
- geometric definition of higher category
- algebraic definition of higher category
- stable homotopy theory

A **$(-1)$-groupoid** or **(-1)-type** is a truth value, or equivalently an (?1)-truncated object in ∞Grpd. By excluded middle, this is either the empty groupoid (false) or the terminal groupoid (true, the point).

Compare the concept of 0-groupoid (a set) and (?2)-groupoid (which is trivial). The point of $(-1)$-groupoids is that they complete some patterns in the periodic table of $n$-categories. (They also shed light on the theory of homotopy groups and n-stuff.)

For example, there should be a $0$-category of $(-1)$-groupoids; a $0$-category is also a set, and this set is the set of truth values: classically

$(-1)Grpd := \{\bot, \top\}$

Actually, since for other values of $n$, n-groupoids form not just an $(n+1)$-category but an $(n+1,1)$-category, we should expect the $0$-category of $(-1)$-groupoids to be a $(0,1)$-category, or $1$-poset. This simply means a poset, and indeed truth values do always form a poset, classically ($\bot \leq \top$).

If we equip the category of $(-1)$-groupoids with the monoidal structure of conjunction (the logical AND operation), then a groupoid enriched over this is a setoid, and a category enriched over it is a proset. Up to equivalence of categories, these are the same as a set (a $0$-groupoid) and a poset (a (0,1)-category); this fits the patterns of the periodic table.

See (?1)-category? for more on this sort of negative thinking.

homotopy level | n-truncation | homotopy theory | higher category theory | higher topos theory | homotopy type theory |
---|---|---|---|---|---|

h-level 0 | (-2)-truncated | contractible space | (-2)-groupoid | true/unit type/contractible type | |

h-level 1 | (-1)-truncated | contractible-if-inhabited | (-1)-groupoid/truth value | (0,1)-sheaf/ideal | mere proposition/h-proposition |

h-level 2 | 0-truncated | homotopy 0-type | 0-groupoid/set | sheaf | h-set |

h-level 3 | 1-truncated | homotopy 1-type | 1-groupoid/groupoid | (2,1)-sheaf/stack | h-groupoid |

h-level 4 | 2-truncated | homotopy 2-type | 2-groupoid | (3,1)-sheaf/2-stack | h-2-groupoid |

h-level 5 | 3-truncated | homotopy 3-type | 3-groupoid | (4,1)-sheaf/3-stack | h-3-groupoid |

h-level $n+2$ | $n$-truncated | homotopy n-type | n-groupoid | (n+1,1)-sheaf/n-stack | h-$n$-groupoid |

h-level $\infty$ | untruncated | homotopy type | ∞-groupoid | (∞,1)-sheaf/∞-stack | h-$\infty$-groupoid |

Last revised on February 2, 2017 at 01:27:39. See the history of this page for a list of all contributions to it.