Greatest element
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In mathematics, especially in order theory, the greatest element of a subset S of a partially ordered set (poset) is an element of S which is greater than or equal to any other element of S. The term least element is defined dually. A bounded poset is a poset that has both a greatest element and a least element.
Formally, given a partially ordered set (P, ≤), then an element g of a subset S of P is the greatest element of S if
- s ≤ g, for all elements s of S.
Hence, the greatest element of S is an upper bound of S that is contained within this subset. It is necessarily unique. By using ≥ instead of ≤ in the above definition, one defines the least element of S.
Like upper bounds, greatest elements may fail to exist. Even if a set has some upper bounds, it need not have a greatest element, as the example of the real numbers strictly smaller than 1 shows. This also demonstrates that the existence of a least upper bound (the number 1 in this case) does not imply the existence of a greatest element either. Similar conclusions hold for least elements. A finite chain always has a greatest and a least element.
Greatest elements of a partially ordered subset must not be confused with maximal elements of such a set which are elements that are not smaller than any other element. In some special cases, such as when dealing with totally ordered sets, both terms do indeed coincide; however, a poset can have several maximal elements, but no greatest element.
The least and greatest elements of the whole partially ordered set play a special role and are also called bottom and top or zero (0) and unit (1), respectively. The latter notation of 0 and 1 is only used when no confusion is likely, i.e. when one is not talking about partial orders of numbers that already contain elements 0 and 1. The existence of least and greatest elements is a special completeness property of a partial order. Bottom and top are often represented by the symbols ⊥ and ⊤, respectively.
Further introductory information is found in the article on order theory.
[edit] Reference
- Davey, B.A., and Priestley, H. A. (2002). Introduction to Lattices and Order, Second Edition, Cambridge University Press. ISBN 0-521-78451-4.
