User:Dfeuer/Cone Compatible with Group Induces Transitive Compatible Relation

Theorem
Let $(G,\circ)$ be a group.

Let $C \subseteq G$ be a User:Dfeuer/Definition:Cone Compatible with Operation.

Let the relation $\mathcal R$ be defined as follows:

If $x,y \in G$, then $x \mathrel{\mathcal R} y$ iff $y \circ x^{-1} \in C$.

Then $\mathcal R$ is a transitive relation compatible with $\circ$.

Transitive
Let $x,y,z \in G$.

Let $x \mathrel{\mathcal R} y$ and $y \mathrel{\mathcal R} z$.

Then $y \circ x^{-1} \in C$ and $z \circ y^{-1} \in C$.

Thus by the definition of a compatible cone:
 * $(z \circ y^{-1}) \circ (y \circ x^{-1}) \in C$

By associativity and the definition of inverse:
 * $z \circ x^{-1} \in C$

Thus $x \mathrel{\mathcal R} z$.

Compatible
Let $x,y,z \in G$.

Let $x \mathrel{\mathcal R} y$.

Then $y \circ x^{-1} \in C$.

$(y \circ z) \circ (x \circ z)^{-1} = (y \circ z) \circ (z^{-1} \circ x^{-1}) = y \circ x^{-1} \in C$.

Thus $(y \circ z) \mathrel{\mathcal R} (x \circ z)$.

Now $(z \circ x)^{-1} \circ (z \circ y) = x^{-1} \circ y \in C$, so by the definition of a compatible cone:

$(z \circ y) \circ (z \circ x)^{-1} \in C$

Thus $z \circ x \mathrel{\mathcal R} z \circ y$.