Ordering in terms of Addition
Theorem
Let $\struct {S, \circ, \preceq}$ be a naturally ordered semigroup.
Then $\forall m, n \in S$:
- $m \preceq n \iff \exists p \in S: m \circ p = n$
Proof
Necessary Condition
From Naturally Ordered Semigroup Axiom $\text {NO} 3$: Existence of Product, we have:
- $\forall m, n \in S: m \preceq n \implies \exists p \in S: m \circ p = n$
$\Box$
Sufficient Condition
Suppose that $m \circ p = n$.
| \(\ds 0\) | \(\preceq\) | \(\ds p\) | Definition of Zero of Naturally Ordered Semigroup | |||||||||||
| \(\ds \leadsto \ \ \) | \(\ds m \circ 0\) | \(\preceq\) | \(\ds m \circ p\) | $\preceq$ is compatible with $\circ$ | ||||||||||
| \(\ds \leadsto \ \ \) | \(\ds m\) | \(\preceq\) | \(\ds n\) | Zero is Identity in Naturally Ordered Semigroup |
$\Box$
So $\forall m, n \in S$:
- $m \preceq n \iff \exists p \in S: m \circ p = n$
$\blacksquare$
Sources
- 1965: Seth Warner: Modern Algebra ... (previous) ... (next): Chapter $\text {III}$: The Natural Numbers: $\S 16$: The Natural Numbers: Theorem $16.2$