Order type

Three well-orderings on the set of natural numbers with distinct order types (top to bottom): ${\displaystyle \omega }$, ${\displaystyle \omega +5}$, and ${\displaystyle \omega +\omega }$.

Every well-ordered set is order-equivalent to exactly one ordinal number. The ordinal numbers are taken to be the canonical representatives of their classes, and so the order type of a well-ordered set is usually identified with the corresponding ordinal. For example, the order type of the natural numbers is ω.

The order type of a well-ordered set V is sometimes expressed as ord(V).[1]

For example, consider the set V of even ordinals less than ω ⋅ 2 + 7:

${\displaystyle V=\{0,2,4,\ldots$ ;\omega ,\omega +2,\omega +4,\ldots ;\omega \cdot 2,\omega \cdot 2+2,\omega \cdot 2+4,\omega \cdot 2+6\}.}

Its order type is:

${\displaystyle \operatorname {ord} (V)=\omega \cdot 2+4=\{0,1,2,\ldots$ ;\omega ,\omega +1,\omega +2,\ldots ;\omega \cdot 2,\omega \cdot 2+1,\omega \cdot 2+2,\omega \cdot 2+3\},}

because there are 2 separate lists of counting and 4 in sequence at the end.

Any countable totally ordered set can be mapped injectively into the rational numbers in an order-preserving way. Any dense countable totally ordered set with no highest and no lowest element can be mapped bijectively onto the rational numbers in an order-preserving way.

The order type of the rationals is usually denoted ${\displaystyle \eta }$. If a set S has order type ${\displaystyle \sigma }$, the order type of the dual of S (the reversed order) is denoted ${\displaystyle \sigma ^{*}}$.

• Well-order

• Weisstein, Eric W. "Order Type". MathWorld.