Difference between revisions of "Invariant of an equivalence relation"

Latest revision as of 18:58, 9 November 2016

Note: see invariant for other uses of the term.

Definition

Let [ilmath]S[/ilmath] be a set and let [ilmath]\sim\subseteq S\times S[/ilmath] be an equivalence relation^{[Note 1]} on [ilmath]S[/ilmath], let [ilmath]W[/ilmath]^{[Note 2]} be any set and let [ilmath]f:S\rightarrow W[/ilmath] be any function from [ilmath]S[/ilmath] to [ilmath]W[/ilmath]. Then^[1]:

• We say "[ilmath]f[/ilmath] is an invariant of [ilmath]\sim[/ilmath]" if^{[Note 3]}:
  • [ilmath]\forall a,b\in S[a\sim b\implies f(a)=f(b)][/ilmath] - in other words, [ilmath]f[/ilmath] is constant on the equivalence classes of [ilmath]\sim[/ilmath].

Complete invariant

With the setup of [ilmath]S[/ilmath], [ilmath]W[/ilmath], [ilmath]\sim[/ilmath] and [ilmath]f:S\rightarrow W[/ilmath] as above define a "complete invariant" as follows^[1]:

• "[ilmath]f[/ilmath] is a complete invariant of [ilmath]\sim[/ilmath]" if^{[Note 3]}:
  • [ilmath]\forall a,b\in S[a\sim b\iff f(a)=f(b)][/ilmath] - in other words, [ilmath]f[/ilmath] is constant on and distinct on the equivalence classes of [ilmath]\sim[/ilmath].

Terminology

It's hard to be formal in English, however we may say any of the following:

• "[ilmath]f[/ilmath] is an invariant of [ilmath]\sim[/ilmath]"^[1]
• "[ilmath]\sim[/ilmath] is invariant under [ilmath]f[/ilmath]"
  • This makes sense as we're saying the [ilmath]a\sim b[/ilmath] property holds (doesn't vary) "under" (think "image of [ilmath]A[/ilmath] under [ilmath]f[/ilmath]"-like terminology) [ilmath]f[/ilmath], that [ilmath]f(a)=f(b)[/ilmath]
• "[ilmath]\sim[/ilmath] invariance of [ilmath]f[/ilmath]"
  • This works better when the relations have names, eg "equality invariance of Alec's heuristic" (that's a made up example) and this would be a proposition or a claim.

Examples and instances

• Homotopy invariance of path concatenation
  • Homotopy invariance of loop concatenation

TODO: Create a category and start collecting

See also

• Complete system of invariants - a finite set of complete invariants really.
• Set of canonical forms - a subset of [ilmath]S[/ilmath], [ilmath]C\in\mathcal{P}(S)[/ilmath], such that there exists a unique [ilmath]c\in C[/ilmath] such that [ilmath]c\sim s[/ilmath]
  • An equivalent condition to the axiom of choice is that every partition has a set of representatives that's closely related. Be warned

Notes

1. ↑ keep in mind that equality is itself an equivalence relation
2. ↑ Think of [ilmath]W[/ilmath] as [ilmath]W\text{hatever} [/ilmath] - as usual (except in Linear Algebra where [ilmath]W[/ilmath] is quite often used for vector spaces
3. ↑ ^{3.0 3.1} See "definitions and iff"

References

1. ↑ ^{1.0 1.1 1.2} Advanced Linear Algebra - Steven Roman