Contents

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

1. a term of circle type whose interpretation is as the base point of the circle,

2. 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.

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

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

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:

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

$\Omega(S^1)=\mathbb{Z}$

There are several proofs in the HoTT book that the loop space $\Omega(S^1)$ of the circle is the integers $\mathbb{Z}$. (Any such proof requires the univalence axiom, since without that it is consistent that $S^1$ is contractible. Indeed, $S^1$ is contractible if and only if UIP holds.)

See also

• 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)