In
mathematics
Mathematics is an area of knowledge that includes the topics of numbers, formulas and related structures, shapes and the spaces in which they are contained, and quantities and their changes. These topics are represented in modern mathematics ...
, a well-order (or well-ordering or well-order relation) on a
set ''S'' is a
total order on ''S'' with the property that every
non-empty subset
In mathematics, Set (mathematics), set ''A'' is a subset of a set ''B'' if all Element (mathematics), elements of ''A'' are also elements of ''B''; ''B'' is then a superset of ''A''. It is possible for ''A'' and ''B'' to be equal; if they are ...
of ''S'' has a
least element in this ordering. The set ''S'' together with the well-order
relation is then called a well-ordered set. In some academic articles and textbooks these terms are instead written as wellorder, wellordered, and wellordering or well order, well ordered, and well ordering.
Every non-empty well-ordered set has a least element. Every element ''s'' of a well-ordered set, except a possible
greatest element, has a unique successor (next element), namely the least element of the subset of all elements greater than ''s''. There may be elements besides the least element which have no predecessor (see below for an example). A well-ordered set ''S'' contains for every subset ''T'' with an upper bound a
least upper bound, namely the least element of the subset of all upper bounds of ''T'' in ''S''.
If ≤ is a
non-strict well ordering, then < is a strict well ordering. A relation is a strict well ordering if and only if it is a
well-founded strict total order
In mathematics, a total or linear order is a partial order in which any two elements are comparable. That is, a total order is a binary relation \leq on some set X, which satisfies the following for all a, b and c in X:
# a \leq a ( reflexi ...
. The distinction between strict and non-strict well orders is often ignored since they are easily interconvertible.
Every well-ordered set is uniquely
order isomorphic
In the mathematical field of order theory, an order isomorphism is a special kind of monotone function that constitutes a suitable notion of isomorphism for partially ordered sets (posets). Whenever two posets are order isomorphic, they can be cons ...
to a unique
ordinal number
In set theory, an ordinal number, or ordinal, is a generalization of ordinal numerals (first, second, th, etc.) aimed to extend enumeration to infinite sets.
A finite set can be enumerated by successively labeling each element with the least n ...
, called the
order type of the well-ordered set. The
well-ordering theorem, which is equivalent to the
axiom of choice, states that every set can be well ordered. If a set is well ordered (or even if it merely admits a
well-founded relation), the proof technique of
transfinite induction can be used to prove that a given statement is true for all elements of the set.
The observation that the
natural numbers
In mathematics, the natural numbers are those numbers used for counting (as in "there are ''six'' coins on the table") and ordering (as in "this is the ''third'' largest city in the country").
Numbers used for counting are called ''cardinal n ...
are well ordered by the usual less-than relation is commonly called the
well-ordering principle (for natural numbers).
Ordinal numbers
Every well-ordered set is uniquely
order isomorphic
In the mathematical field of order theory, an order isomorphism is a special kind of monotone function that constitutes a suitable notion of isomorphism for partially ordered sets (posets). Whenever two posets are order isomorphic, they can be cons ...
to a unique
ordinal number
In set theory, an ordinal number, or ordinal, is a generalization of ordinal numerals (first, second, th, etc.) aimed to extend enumeration to infinite sets.
A finite set can be enumerated by successively labeling each element with the least n ...
, called the
order type of the well-ordered set. The position of each element within the ordered set is also given by an ordinal number. In the case of a finite set, the basic operation of
counting, to find the ordinal number of a particular object, or to find the object with a particular ordinal number, corresponds to assigning ordinal numbers one by one to the objects. The size (number of elements,
cardinal number) of a finite set is equal to the order type. Counting in the everyday sense typically starts from one, so it assigns to each object the size of the initial segment with that object as last element. Note that these numbers are one more than the formal ordinal numbers according to the isomorphic order, because these are equal to the number of earlier objects (which corresponds to counting from zero). Thus for finite ''n'', the expression "''n''-th element" of a well-ordered set requires context to know whether this counts from zero or one. In a notation "β-th element" where β can also be an infinite ordinal, it will typically count from zero.
For an infinite set the order type determines the
cardinality
In mathematics, the cardinality of a set is a measure of the number of elements of the set. For example, the set A = \ contains 3 elements, and therefore A has a cardinality of 3. Beginning in the late 19th century, this concept was generalized ...
, but not conversely: well-ordered sets of a particular cardinality can have many different order types (see , below, for an example). For a
countably infinite
In mathematics, a set is countable if either it is finite or it can be made in one to one correspondence with the set of natural numbers. Equivalently, a set is ''countable'' if there exists an injective function from it into the natural numbers; ...
set, the set of possible order types is uncountable.
Examples and counterexamples
Natural numbers
The standard ordering ≤ of the
natural numbers is a well ordering and has the additional property that every non-zero natural number has a unique predecessor.
Another well ordering of the natural numbers is given by defining that all even numbers are less than all odd numbers, and the usual ordering applies within the evens and the odds:
:0 2 4 6 8 ... 1 3 5 7 9 ...
This is a well-ordered set of order type ω + ω. Every element has a successor (there is no largest element). Two elements lack a predecessor: 0 and 1.
Integers
Unlike the standard ordering ≤ of the
natural numbers, the standard ordering ≤ of the
integers is not a well ordering, since, for example, the set of
negative integers does not contain a least element.
The following relation ''R'' is an example of well ordering of the integers: ''
x R y''
if and only if one of the following conditions holds:
# ''x'' = 0
# ''x'' is positive, and ''y'' is negative
# ''x'' and ''y'' are both positive, and ''x'' ≤ ''y''
# ''x'' and ''y'' are both negative, and , ''x'', ≤ , ''y'',
This relation ''R'' can be visualized as follows:
:0 1 2 3 4 ... −1 −2 −3 ...
''R'' is isomorphic to the
ordinal number
In set theory, an ordinal number, or ordinal, is a generalization of ordinal numerals (first, second, th, etc.) aimed to extend enumeration to infinite sets.
A finite set can be enumerated by successively labeling each element with the least n ...
ω + ω.
Another relation for well ordering the integers is the following definition: ''x'' ≤
z ''y''
if and only if (, ''x'', < , ''y'', or (, ''x'', = , ''y'', and ''x'' ≤ ''y'')). This well order can be visualized as follows:
: 0 −1 1 −2 2 −3 3 −4 4 ...
This has the
order type ω.
Reals
The standard ordering ≤ of any
real interval is not a well ordering, since, for example, the
open interval
In mathematics, a (real) interval is a set of real numbers that contains all real numbers lying between any two numbers of the set. For example, the set of numbers satisfying is an interval which contains , , and all numbers in between. Other ...
(0, 1) ⊆
,1does not contain a least element. From the
ZFC axioms of set theory (including the
axiom of choice) one can show that there is a well order of the reals. Also
Wacław Sierpiński proved that ZF + GCH (the
generalized continuum hypothesis) imply the axiom of choice and hence a well order of the reals. Nonetheless, it is possible to show that the ZFC+GCH axioms alone are not sufficient to prove the existence of a definable (by a formula) well order of the reals.
However it is consistent with ZFC that a definable well ordering of the reals exists—for example, it is consistent with ZFC that
V=L
The axiom of constructibility is a possible axiom for set theory in mathematics that asserts that every set is constructible. The axiom is usually written as ''V'' = ''L'', where ''V'' and ''L'' denote the von Neumann universe and the constructib ...
, and it follows from ZFC+V=L that a particular formula well orders the reals, or indeed any set.
An uncountable subset of the real numbers with the standard ordering ≤ cannot be a well order: Suppose ''X'' is a subset of R well ordered by ≤. For each ''x'' in ''X'', let ''s''(''x'') be the successor of ''x'' in ≤ ordering on ''X'' (unless ''x'' is the last element of ''X''). Let ''A'' = whose elements are nonempty and disjoint intervals. Each such interval contains at least one rational number, so there is an
injective function
In mathematics, an injective function (also known as injection, or one-to-one function) is a function that maps distinct elements of its domain to distinct elements; that is, implies . (Equivalently, implies in the equivalent contrapositiv ...
from ''A'' to Q. There is an injection from ''X'' to ''A'' (except possibly for a last element of ''X'' which could be mapped to zero later). And it is well known that there is an injection from ''Q'' to the natural numbers (which could be chosen to avoid hitting zero). Thus there is an injection from ''X'' to the natural numbers which means that ''X'' is countable. On the other hand, a countably infinite subset of the reals may or may not be a well order with the standard "≤". For example,
* The natural numbers are a well order under the standard ordering ≤.
* The set has no least element and is therefore not a well order under standard ordering ≤.
Examples of well orders:
*The set of numbers has order type ω.
*The set of numbers has order type ω
2. The previous set is the set of
limit points within the set. Within the set of real numbers, either with the ordinary topology or the order topology, 0 is also a limit point of the set. It is also a limit point of the set of limit points.
*The set of numbers ∪ has order type ω + 1. With the
order topology of this set, 1 is a limit point of the set. With the ordinary topology (or equivalently, the order topology) of the real numbers it is not.
Equivalent formulations
If a set is
totally ordered, then the following are equivalent to each other:
# The set is well ordered. That is, every nonempty subset has a least element.
#
Transfinite induction works for the entire ordered set.
# Every strictly decreasing sequence of elements of the set must terminate after only finitely many steps (assuming the
axiom of dependent choice In mathematics, the axiom of dependent choice, denoted by \mathsf , is a weak form of the axiom of choice ( \mathsf ) that is still sufficient to develop most of real analysis. It was introduced by Paul Bernays in a 1942 article that explores whi ...
).
# Every subordering is isomorphic to an initial segment.
Order topology
Every well-ordered set can be made into a
topological space by endowing it with the
order topology.
With respect to this topology there can be two kinds of elements:
*
isolated points — these are the minimum and the elements with a predecessor.
*
limit points — this type does not occur in finite sets, and may or may not occur in an infinite set; the infinite sets without limit point are the sets of order type ω, for example N.
For subsets we can distinguish:
*Subsets with a maximum (that is, subsets which are
bounded
Boundedness or bounded may refer to:
Economics
* Bounded rationality, the idea that human rationality in decision-making is bounded by the available information, the cognitive limitations, and the time available to make the decision
* Bounded e ...
by themselves); this can be an isolated point or a limit point of the whole set; in the latter case it may or may not be also a limit point of the subset.
*Subsets which are unbounded by themselves but bounded in the whole set; they have no maximum, but a supremum outside the subset; if the subset is non-empty this supremum is a limit point of the subset and hence also of the whole set; if the subset is empty this supremum is the minimum of the whole set.
*Subsets which are unbounded in the whole set.
A subset is
cofinal in the whole set if and only if it is unbounded in the whole set or it has a maximum which is also maximum of the whole set.
A well-ordered set as topological space is a
first-countable space if and only if it has order type less than or equal to ω
1 (
omega-one), that is, if and only if the set is
countable or has the smallest
uncountable order type.
See also
*
Tree (set theory), generalization
*
Ordinal number
In set theory, an ordinal number, or ordinal, is a generalization of ordinal numerals (first, second, th, etc.) aimed to extend enumeration to infinite sets.
A finite set can be enumerated by successively labeling each element with the least n ...
*
Well-founded set
In mathematics, a binary relation ''R'' is called well-founded (or wellfounded) on a class ''X'' if every non-empty subset ''S'' ⊆ ''X'' has a minimal element with respect to ''R'', that is, an element ''m'' not related by ''s&n ...
*
Well partial order
In mathematics, specifically order theory, a well-quasi-ordering or wqo is a quasi-ordering such that any infinite sequence of elements x_0, x_1, x_2, \ldots from X contains an increasing pair x_i \leq x_j with i x_2> \cdots) nor infinite sequen ...
*
Prewellordering
*
Directed set
References
*
{{Order theory
Binary relations
Order theory
Ordinal numbers
Wellfoundedness