Partition of sums of squares

In mathematics, a partial equivalence relation (often abbreviated as PER) ${\displaystyle R}$ on a set ${\displaystyle X}$ is a relation that is symmetric and transitive. In other words, it holds for all ${\displaystyle a,b,c\in X}$ that:

1. if ${\displaystyle aRb}$, then ${\displaystyle bRa}$ (symmetry)
2. if ${\displaystyle aRb}$ and ${\displaystyle bRc}$, then ${\displaystyle aRc}$ (transitivity)

If ${\displaystyle R}$ is also reflexive, then ${\displaystyle R}$ is an equivalence relation.

In a set-theoretic context, there is a simple structure to the general PER ${\displaystyle R}$ on ${\displaystyle X}$: it is an equivalence relation on the subset ${\displaystyle Y=\{x\in X|x\,R\,x\}\subseteq X}$. (${\displaystyle Y}$ is the subset of ${\displaystyle X}$ such that in the complement of ${\displaystyle Y}$ (${\displaystyle X\setminus Y}$) no element is related by ${\displaystyle R}$ to any other.) By construction, ${\displaystyle R}$ is reflexive on ${\displaystyle Y}$ and therefore an equivalence relation on ${\displaystyle Y}$. Notice that ${\displaystyle R}$ is actually only true on elements of ${\displaystyle Y}$: if ${\displaystyle xRy}$, then ${\displaystyle yRx}$ by symmetry, so ${\displaystyle xRx}$ and ${\displaystyle yRy}$ by transitivity. Conversely, given a subset Y of X, any equivalence relation on Y is automatically a PER on X.

PERs are therefore used mainly in computer science, type theory and constructive mathematics, particularly to define setoids, sometimes called partial setoids. The action of forming one from a type and a PER is analogous to the operations of subset and quotient in classical set-theoretic mathematics.

Examples

A simple example of a PER that is not an equivalence relation is the empty relation ${\displaystyle R=\emptyset }$ (unless ${\displaystyle X=\emptyset }$, in which case the empty relation is an equivalence relation (and is the only relation on ${\displaystyle X}$)).

Kernels of partial functions

For another example of a PER, consider a set ${\displaystyle A}$ and a partial function ${\displaystyle f}$ that is defined on some elements of ${\displaystyle A}$ but not all. Then the relation ${\displaystyle \approx }$ defined by

${\displaystyle x\approx y}$ if and only if ${\displaystyle f}$ is defined at ${\displaystyle x}$, ${\displaystyle f}$ is defined at ${\displaystyle y}$, and ${\displaystyle f(x)=f(y)}$

is a partial equivalence relation but not an equivalence relation. It possesses the symmetry and transitivity properties, but it is not reflexive since if ${\displaystyle f(x)}$ is not defined then ${\displaystyle x\not \approx x}$ — in fact, for such an ${\displaystyle x}$ there is no ${\displaystyle y\in A}$ such that ${\displaystyle x\approx y}$. (It follows immediately that the subset of ${\displaystyle A}$ for which ${\displaystyle \approx }$ is an equivalence relation is precisely the subset on which ${\displaystyle f}$ is defined.)

Functions respecting equivalence relations

Let X and Y be sets equipped with equivalence relations (or PERs) ${\displaystyle \approx _{X},\approx _{Y}}$. For ${\displaystyle f,g:X\to Y}$, define ${\displaystyle f\approx g}$ to mean:

${\displaystyle \forall x_{0}\;x_{1},\quad x_{0}\approx _{X}x_{1}\Rightarrow f(x_{0})\approx _{Y}g(x_{1})}$

then ${\displaystyle f\approx f}$ means that f induces a well-defined function of the quotients ${\displaystyle X/\approx _{X}\;\to \;Y/\approx _{Y}}$. Thus, the PER ${\displaystyle \approx }$ captures both the idea of definedness on the quotients and of two functions inducing the same function on the quotient.

References

• Mitchell, John C. Foundations of programming languages. MIT Press, 1996.

See also

• Equivalence relation
• Binary relation