Homotopy Type Theory UMyn8W7b (Rev #53)

Euclidean semirings

Given a additively cancellative commutative semiring RR, a term e:Re:R is left cancellative if for all a:Ra:R and b:Rb:R, ea=ebe \cdot a = e \cdot b implies a=ba = b.

isLeftCancellative(e) a:R b:R(ea=eb)(a=b)\mathrm{isLeftCancellative}(e) \coloneqq \prod_{a:R} \prod_{b :R}(e \cdot a = e \cdot b) \to (a = b)

A term e:Re:R is right cancellative if for all a:Ra:R and b:Rb:R, ae=bea \cdot e = b \cdot e implies a=ba = b.

isRightCancellative(e) a:R b:R(ae=be)(a=b)\mathrm{isRightCancellative}(e) \coloneqq \prod_{a:R} \prod_{b :R}(a \cdot e = b \cdot e) \to (a = b)

An term e:Re:R is cancellative if it is both left cancellative and right cancellative.

isCancellative(e)isLeftCancellative(e)×isRightCancellative(e)\mathrm{isCancellative}(e) \coloneqq \mathrm{isLeftCancellative}(e) \times \mathrm{isRightCancellative}(e)

The multiplicative submonoid of cancellative elements in RR is the subset of all cancellative elements in RR

Can(R) e:RisCancellative(e)\mathrm{Can}(R) \coloneqq \sum_{e:R} \mathrm{isCancellative}(e)

A Euclidean semiring is a additively cancellative commutative semiring RR for which there exists a function d:Can(R)d \colon \mathrm{Can}(R) \to \mathbb{N} from the multiplicative submonoid of cancellative elements in RR to the natural numbers, often called a degree function, a function ()÷():R×Can(R)R(-)\div(-):R \times \mathrm{Can}(R) \to R called the division function, and a function ()%():R×Can(R)R(-)\;\%\;(-):R \times \mathrm{Can}(R) \to R called the remainder function, such that for all aRa \in R and bCan(R)b \in \mathrm{Can}(R), a=(a÷b)b+(a%b)a = (a \div b) \cdot b + (a\;\%\; b) and either a%b=0a\;\%\; b = 0 or d(a%b)<d(g)d(a\;\%\; b) \lt d(g).

Non-cancellative and non-invertible elements

Given a ring RR, an element xRx \in R is non-cancellative if: if there is an element yCan(R)y \in \mathrm{Can}(R) with injection i:Can(R)Ri:\mathrm{Can}(R) \to R such that i(y)=xi(y) = x, then 0=10 = 1. An element xRx \in R is non-invertible if: if there is an element yR ×y \in R^\times with injection j:R ×Rj:R^\times \to R such that j(y)=xj(y) = x, then 0=10 = 1.

To the real numbers

  • Q-vector space

  • free Q-vector spaces?

  • strictly ordered Q-vector space?

  • Archimedean Q-vector space?

Revision on June 2, 2022 at 15:12:36 by Anonymous?. See the history of this page for a list of all contributions to it.