nLab circle type

Context

Type theory

natural deduction metalanguage, practical foundations

judgement
hypothetical judgement, sequent
- antecedents $\vdash$ consequent, succedents

type theory (dependent, intensional, observational type theory, homotopy type theory)

calculus of constructions

theory, axiom
proposition/type (propositions as types)
definition/proof/program (proofs as programs)
theorem

computational trinitarianism =
propositions as types +programs as proofs +relation type theory/category theory

logic	set theory (internal logic of)	category theory	type theory
proposition	set	object	type
predicate	family of sets	display morphism	dependent type
proof	element	generalized element	term/program
cut rule		composition of classifying morphisms / pullback of display maps	substitution
introduction rule for implication		counit for hom-tensor adjunction	lambda
elimination rule for implication		unit for hom-tensor adjunction	application
cut elimination for implication		one of the zigzag identities for hom-tensor adjunction	beta reduction
identity elimination for implication		the other zigzag identity for hom-tensor adjunction	eta conversion
true	singleton	terminal object/(-2)-truncated object	h-level 0-type/unit type
false	empty set	initial object	empty type
proposition, truth value	subsingleton	subterminal object/(-1)-truncated object	h-proposition, mere proposition
logical conjunction	cartesian product	product	product type
disjunction	disjoint union (support of)	coproduct ((-1)-truncation of)	sum type (bracket type of)
implication	function set (into subsingleton)	internal hom (into subterminal object)	function type (into h-proposition)
negation	function set into empty set	internal hom into initial object	function type into empty type
universal quantification	indexed cartesian product (of family of subsingletons)	dependent product (of family of subterminal objects)	dependent product type (of family of h-propositions)
existential quantification	indexed disjoint union (support of)	dependent sum ((-1)-truncation of)	dependent sum type (bracket type of)
logical equivalence	bijection set	object of isomorphisms	equivalence type
	support set	support object/(-1)-truncation	propositional truncation/bracket type
		n-image of morphism into terminal object/n-truncation	n-truncation modality
equality	diagonal function/diagonal subset/diagonal relation	path space object	identity type/path type
completely presented set	set	discrete object/0-truncated object	h-level 2-type/set/h-set
set	set with equivalence relation	internal 0-groupoid	Bishop set/setoid with its pseudo-equivalence relation an actual equivalence relation
	equivalence class/quotient set	quotient	quotient type
induction		colimit	inductive type, W-type, M-type
higher induction		higher colimit	higher inductive type
-		0-truncated higher colimit	quotient inductive type
coinduction		limit	coinductive type
	preset		type without identity types
	set of truth values	subobject classifier	type of propositions
domain of discourse	universe	object classifier	type universe
modality		closure operator, (idempotent) monad	modal type theory, monad (in computer science)
linear logic		(symmetric, closed) monoidal category	linear type theory/quantum computation
proof net		string diagram	quantum circuit
(absence of) contraction rule		(absence of) diagonal	no-cloning theorem
		synthetic mathematics	domain specific embedded programming language

homotopy levels

semantics

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Idea
Definition

In natural deduction
As a suspension
As a coequalizer
Using torsors

Properties

Induction and recursion principles
Extensionality principle of the circle type
H-space structures on the circle type

Related concepts
References

Idea

The circle type is an axiomatization of the homotopy type of the (shape of) the circle in the context of homotopy type theory.

Definition

As a higher inductive type, the circle is given by

Inductive Circle : Type
  | base : Circle
  | loop : Id Circle base base

This says that the type is inductively constructed from

a term of circle type whose interpretation is as the base point of the circle,
a term of the identity type of paths between these two terms, which interprets as the 1-cell of the circle

$base \stackrel{loop}{\to} base \,$

Hence a non-constant path from the base point to itself.

In natural deduction

Let $\mathrm{Id}_A(a, b)$ denote the identification type between elements $a:A$ and $b:A$ of type $A$ , and let $\mathrm{hId}_{x:A.B(x)}(a, b, p, y, z)$ denote the heterogeneous identification type between elements $y:B(a)$ and $z:B(b)$ of type family $x:A \vdash B(x)$ , given elements $a:A$ and $b:A$ and identification $p:\mathrm{Id}_A(a, b)$ . Let $\mathrm{apd}_{x:A.B(x)}(f, a, b, p)$ denote the dependent function application of the dependent function $f:\prod_{x:A} B(x)$ to the identification $p:\mathrm{Id}_A(a, b)$

In the natural deduction formulation of dependent type theory, the circle type is given by the following inference rules:

Formation rules for the circle type:

\frac{\Gamma \; \mathrm{ctx}}{\Gamma \vdash S^1 \; \mathrm{type}}

Introduction rules for the circle type:

\frac{\Gamma \; \mathrm{ctx}}{\Gamma \vdash *:S^1} \qquad \frac{\Gamma \; \mathrm{ctx}}{\Gamma \vdash \mathcal{l}:\mathrm{Id}_{S^1}(*,*)}

Elimination rules for the circle type:

\frac{\Gamma, x:S^1 \vdash C(x) \; \mathrm{type} \quad \Gamma \vdash c_*:C(*) \quad \Gamma \vdash c_\mathcal{l}:\mathrm{hId}_{x:S^1.C(x)}(*, *, \mathcal{l}, c_*, c_*)}{\Gamma, x:S^1 \vdash \mathrm{ind}_{S^1}^{x:S^1.C(x)}(c_*, c_\mathcal{l})(x):C(x)}

Computation rules for the circle type:

\frac{\Gamma, x:S^1 \vdash C(x) \; \mathrm{type} \quad \Gamma \vdash c_*:C(*) \quad \Gamma \vdash c_\mathcal{l}:\mathrm{hId}_{x:S^1.C(x)}(*, *, \mathcal{l}, c_*, c_*)}{\Gamma \vdash \beta_{S^1}^{*}(c_*, c_\mathcal{l}):\mathrm{Id}_{C(*)}(\mathrm{ind}_{S^1}^{x:S^1.C(x)}(c_*, c_\mathcal{l})(*), c_*)}

\frac{\Gamma, x:S^1 \vdash C(x) \; \mathrm{type} \quad \Gamma \vdash c_*:C(*) \quad \Gamma \vdash c_\mathcal{l}:\mathrm{hId}_{x:S^1.C(x)}(*, *, \mathcal{l}, c_*, c_*)}{\Gamma \vdash \beta_{S^1}^{\mathcal{l}}(c_*, c_\mathcal{l}):\mathrm{Id}_{\mathrm{hId}_{x:S^1.C(x)}(*, *, \mathcal{l}, c_*, c_*)}(\mathrm{apd}_{x:S^1.C(x)}(\mathrm{ind}_{S^1}^{x:S^1.C(x)}(c_*, c_\mathcal{l})), c_\mathcal{l}, *, *, \mathcal{l})}

Uniqueness rules for the circle type:

\frac{\Gamma, x:S^1 \vdash C(x) \; \mathrm{type} \quad \Gamma \vdash c:\prod_{x:S^1} C(x) \quad \Gamma \vdash p:S^1 \quad \Gamma \vdash l:\mathrm{Id}_{S^1}(p, p)}{\Gamma\vdash \eta_{S^1}(c, p, l):\mathrm{Id}_{C(p)}(c,\mathrm{ind}_{S^1}^{x:S^1.C(x)}(c(p), \mathrm{apd}_{x:S^1.C(x)}(c, p, p, l))}

The elimination, computation, and uniqueness rules for the circle type state that the circle type satisfy the dependent universal property of the circle type. If the dependent type theory also has dependent sum types and product types, allowing one to define the uniqueness quantifier, the dependent universal property of the circle type could be simplified to the following rule:

\frac{\Gamma, x:S^1 \vdash C(x) \; \mathrm{type} \quad \Gamma \vdash c_*:C(*) \quad \Gamma \vdash c_\mathcal{l}:\mathrm{hId}_{x:S^1.C(x)}(*, *, \mathcal{l}, c_*, c_*)}{\Gamma \vdash \mathrm{up}_{S^1}^{x:S^1.C(x)}(c_*, c_\mathcal{l}):\exists!c:\prod_{x:S^1} C(x).\mathrm{Id}_{C(*)}(c(*), c_*) \times \mathrm{Id}_{\mathrm{hId}_{x:S^1.C(x)}(*, *, \mathcal{l}, c_*, c_*)}(\mathrm{apd}_{x:S^1.C(x)}(c, c_*, c_*, c_\mathcal{l}), c_\mathcal{l})}

As a suspension

The circle type could also be defined as the suspension type $\Sigma \mathbf{2}$ of the type of booleans $\mathbf{2}$ .

As a coequalizer

The circle type could also be defined as the coequalizer type of any two endofunctions on the unit type

\mathbf{1} \rightrightarrows \mathbf{1} \to S^1

Using torsors

The circle can also be defined without HITs using only univalence, as the type of $\mathbb{Z}$ -torsors. One can then prove that this type satisfies the same induction principle (propositionally). This is due to Dan Grayson.

Properties

Induction and recursion principles

Its induction principle says (e.g. UFP13, p. 177) that for

any $P \colon S^1 \to Type$
equipped with a point $base' \colon P(base)$
and a dependent path $loop' \,\colon\, base' =_{loop} base'$ ,

there is $f:\prod_{(x:S^1)} P(x)$ such that:

f(base)=base'\qquad apd_f(loop) = loop'

As a special case, its recursion principle says that given any type $X$ with a point $x:X$ and a loop $l:x=x$ , there is $f:S^1 \to X$ with

f(base)=x\qquad ap_f(loop)=l

Extensionality principle of the circle type

The extensionality principle of the circle type says that there is an equivalence of types between the identification type $\mathrm{Id}_S^1(*,*)$ and the type of integers $\mathbb{Z}$ :

\mathrm{ext}_S^1:\mathrm{Id}_S^1(*,*) \simeq \mathbb{Z}

Equivalently, that the loop space type $\Omega(S^1, *)$ is equivalent to the integers.

Thus, the extensionality principle of the circle type implies that the integers and thus the natural numbers are contractible types if axiom K or uniqueness of identity proofs hold for the entire type theory. If the extensionality principle of the natural numbers also hold in the type theory, then every type is contractible.

One could prove the extensionality principle of the circle type, given a univalent universe where the circle is small relative to the universe. The HoTT book provides a number of such proofs.

H-space structures on the circle type

The type of H-spaces on the circle type is a contractible type.

Related concepts

circle, unit circle, circle group, circle object
interval type
minimal simplicial circle
suspension type
sphere type
homotopy groups of spheres
Jordan curve
lemniscate type?

References

The formalization of the shape homotopy type $ʃ S^1 \simeq \mathbf{B}\mathbb{Z}$ of the circle as a higher inductive type in homotopy type theory, along with a proof that $\Omega ʃS^1\simeq {\mathbb{Z}}$ (and hence $\pi_1(ʃS^1) \simeq \mathbb{Z}$ ):

Dan Licata, Mike Shulman, Calculating the Fundamental Group of the Circle in Homotopy Type Theory, LICS ‘13: Proceedings of the 2013 28th Annual ACM/IEEE Symposium on Logic in Computer Science June 2013 (arXiv:1301.3443, doi:10.1109/LICS.2013.28)

blog announcements:

A formal proof that $\pi_1(S^1) = \mathbb{Z}$

A simpler proof that $\pi_1(S^1) = \mathbb{Z}$

Formalization in proof assistants:

in Coq:

The HoTT Coq library: theories/hit/Circle.v

in Agda:

The HoTT Agda library: homotopy/LoopSpaceCircle.agda

Exposition and review:

Univalent Foundations Project, §8.1 Homotopy Type Theory – Univalent Foundations of Mathematics (2013) [web, pdf]

Alternative construction of the circle type as the type of $\mathbb{Z}$ -torsors:

Marc Bezem, Ulrik Buchholtz, Daniel Grayson, Michael Shulman, Construction of the Circle in UniMath, Journal of Pure and Applied Algebra Volume 225, Issue 10, October 2021, 106687 (arXiv:1910.01856)

Alternative construction of the circle type as a coequalizer:

Mike Shulman, Section 9 of Brouwer’s fixed-point theorem in real-cohesive homotopy type theory, Mathematical Structures in Computer Science Vol 28 (6) (2018): 856-941 (arXiv:1509.07584, doi:10.1017/S0960129517000147)

For the fact that the type of H-space structures on a circle type is contractible:

Ulrik Buchholtz, J. Daniel Christensen, Jarl G. Taxerås Flaten, Egbert Rijke, Central H-spaces and banded types [arXiv:2301.02636]

Last revised on August 2, 2023 at 12:44:13. See the history of this page for a list of all contributions to it.