In the

mathematical Mathematics is a field of study that discovers and organizes methods, Mathematical theory, theories and theorems that are developed and Mathematical proof, proved for the needs of empirical sciences and mathematics itself. There are many ar ...

field of

order theory Order theory is a branch of mathematics that investigates the intuitive notion of order using binary relations. It provides a formal framework for describing statements such as "this is less than that" or "this precedes that". This article intr ...

, a continuum or linear continuum is a generalization of the

real line A number line is a graphical representation of a straight line that serves as spatial representation of numbers, usually graduated like a ruler with a particular origin (geometry), origin point representing the number zero and evenly spaced mark ...

. Formally, a linear continuum is a

linearly ordered set In mathematics, a total order 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 (mathematics), set X, which satisfies the following for all a, b and c in X ...

''S'' of more than one element that is densely ordered, i.e., between any two distinct elements there is another (and hence infinitely many others), and complete, i.e., which "lacks gaps" in the sense that every nonempty

subset In mathematics, a 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 a ...

with an

upper bound In mathematics, particularly in order theory, an upper bound or majorant of a subset of some preordered set is an element of that is every element of . Dually, a lower bound or minorant of is defined to be an element of that is less ...

has a least upper bound in the set. More symbolically:

''S'' has the
least upper bound property In mathematics, the least-upper-bound property (sometimes called completeness, supremum property or l.u.b. property) is a fundamental property of the real numbers. More generally, a partially ordered set has the least-upper-bound property if ever ...
, and
For each ''x'' in ''S'' and each ''y'' in ''S'' with ''x'' < ''y'', there exists ''z'' in ''S'' such that ''x'' < ''z'' < ''y''

set Set, The Set, SET or SETS may refer to: Science, technology, and mathematics Mathematics *Set (mathematics), a collection of elements *Category of sets, the category whose objects and morphisms are sets and total functions, respectively Electro ...

has the least upper bound property, if every nonempty subset of the set that is bounded above has a least upper bound in the set. Linear continua are particularly important in the field of

topology Topology (from the Greek language, Greek words , and ) is the branch of mathematics concerned with the properties of a Mathematical object, geometric object that are preserved under Continuous function, continuous Deformation theory, deformat ...

where they can be used to verify whether an ordered set given the

order topology In mathematics, an order topology is a specific topology that can be defined on any totally ordered set. It is a natural generalization of the topology of the real numbers to arbitrary totally ordered sets. If ''X'' is a totally ordered set, ...

is connected or not. Unlike the standard real line, a linear continuum may be bounded on either side: for example, any (real)

closed interval In mathematics, a real interval is the set of all real numbers lying between two fixed endpoints with no "gaps". Each endpoint is either a real number or positive or negative infinity, indicating the interval extends without a bound. A real in ...

is a linear continuum.

Examples

* The ordered set of

real number In mathematics, a real number is a number that can be used to measure a continuous one- dimensional quantity such as a duration or temperature. Here, ''continuous'' means that pairs of values can have arbitrarily small differences. Every re ...

s, R, with its usual order is a linear continuum, and is the archetypal example. Property b) is trivial, and property a) is simply a reformulation of the completeness axiom. Examples in addition to the real numbers: *sets which are order-isomorphic to the set of real numbers, for example a real

open interval In mathematics, a real interval is the set (mathematics), set of all real numbers lying between two fixed endpoints with no "gaps". Each endpoint is either a real number or positive or negative infinity, indicating the interval extends without ...

, and the same with half-open gaps (note that these are not gaps in the above-mentioned sense) *the

affinely extended real number system In mathematics, the extended real number system is obtained from the real number system \R by adding two elements denoted +\infty and -\infty that are respectively greater and lower than every real number. This allows for treating the potential ...

and order-isomorphic sets, for example the

unit interval In mathematics, the unit interval is the closed interval , that is, the set of all real numbers that are greater than or equal to 0 and less than or equal to 1. It is often denoted ' (capital letter ). In addition to its role in real analysi ...

*the set of real numbers with only +∞ or only −∞ added, and order-isomorphic sets, for example a half-open interval *the long line * The set ''I'' × ''I'' (where × denotes the

Cartesian product In mathematics, specifically set theory, the Cartesian product of two sets and , denoted , is the set of all ordered pairs where is an element of and is an element of . In terms of set-builder notation, that is A\times B = \. A table c ...

and ''I'' = , 1 in the

lexicographic order In mathematics, the lexicographic or lexicographical order (also known as lexical order, or dictionary order) is a generalization of the alphabetical order of the dictionaries to sequences of ordered symbols or, more generally, of elements of a ...

is a linear continuum. Property b) is trivial. To check property a), we define a map, π₁ : ''I'' × ''I'' → ''I'' by ::''π''₁ (''x'', ''y'') = ''x'' :This map is known as the projection map. The projection map is continuous (with respect to the

product topology In topology and related areas of mathematics, a product space is the Cartesian product of a family of topological spaces equipped with a natural topology called the product topology. This topology differs from another, perhaps more natural-seemin ...

on ''I'' × ''I'') and is

surjective In mathematics, a surjective function (also known as surjection, or onto function ) is a function such that, for every element of the function's codomain, there exists one element in the function's domain such that . In other words, for a f ...

. Let ''A'' be a nonempty subset of ''I'' × ''I'' which is bounded above. Consider ''π''₁(''A''). Since ''A'' is bounded above, ''π''₁(''A'') must also be bounded above. Since, ''π''₁(''A'') is a subset of ''I'', it must have a least upper bound (since ''I'' has the least upper bound property). Therefore, we may let ''b'' be the least upper bound of ''π''₁(''A''). If ''b'' belongs to ''π''₁(''A''), then ''b'' × ''I'' will intersect ''A'' at say ''b'' × ''c'' for some ''c'' ∈ ''I''. Notice that since ''b'' × ''I'' has the same

order type In mathematics, especially in set theory, two ordered sets and are said to have the same order type if they are order isomorphic, that is, if there exists a bijection (each element pairs with exactly one in the other set) f\colon X \to Y su ...

of ''I'', the set (''b'' × ''I'') ∩ ''A'' will indeed have a least upper bound ''b'' × ''c, which is the desired least upper bound for ''A''. :If ''b'' does not belong to ''π''₁(''A''), then ''b'' × 0 is the least upper bound of ''A'', for if ''d'' < ''b'', and ''d'' × ''e'' is an upper bound of ''A'', then ''d'' would be a smaller upper bound of ''π''₁(''A'') than ''b'', contradicting the unique property of ''b''.

Non-examples

* The ordered set Q of

rational number In mathematics, a rational number is a number that can be expressed as the quotient or fraction of two integers, a numerator and a non-zero denominator . For example, is a rational number, as is every integer (for example, The set of all ...

s is not a linear continuum. Even though property b) is satisfied, property a) is not. Consider the subset ::''A'' = : of the set of rational numbers. Even though this set is bounded above by any rational number greater than (for instance 3), it has no least upper bound in the rational numbers. (Specifically, for any rational upper bound ''r'' > , ''r''/2 + 1/''r'' is a closer rational upper bound; details at .) * The ordered set of non-negative

integer An integer is the number zero (0), a positive natural number (1, 2, 3, ...), or the negation of a positive natural number (−1, −2, −3, ...). The negations or additive inverses of the positive natural numbers are referred to as negative in ...

s with its usual order is not a linear continuum. Property a) is satisfied (let ''A'' be a subset of the set of non-negative integers that is bounded above. Then ''A'' is finite so it has a maximum, and this maximum is the desired least upper bound of ''A''). On the other hand, property b) is not. Indeed, 5 is a non-negative integer and so is 6, but there exists no non-negative integer that lies strictly between them. * The ordered set ''A'' of nonzero real numbers ::''A'' = (−∞, 0) ∪ (0, +∞) : is not a linear continuum. Property b) is trivially satisfied. However, if ''B'' is the set of negative real numbers: ::''B'' = (−∞, 0) : then ''B'' is a subset of ''A'' which is bounded above (by any element of ''A'' greater than 0; for instance 1), but has no least upper bound in ''A''. Notice that 0 is not a bound for ''B'' since 0 is not an element of ''A''. * Let Z₋ denote the set of negative integers and let ''A'' = (0, 5) ∪ (5, +∞). Let ::''S'' = Z₋ ∪ ''A''. : Then ''S'' satisfies neither property a) nor property b). The proof is similar to the previous examples.

Topological properties

Even though linear continua are important in the study of ordered sets, they do have applications in the mathematical field of

. In fact, we will prove that an ordered set in the

is connected if and only if it is a linear continuum. We will prove one implication, and leave the other one as an exercise. (Munkres explains the second part of the proof in ) Theorem Let ''X'' be an ordered set in the order topology. If ''X'' is connected, then ''X'' is a linear continuum. ''Proof:'' Suppose that ''x'' and ''y'' are elements of ''X'' with ''x'' < ''y''. If there exists no ''z'' in ''X'' such that ''x'' < ''z'' < ''y'', consider the sets: :''A'' = (−∞, ''y'') :''B'' = (''x'', +∞) These sets are disjoint (If ''a'' is in ''A'', ''a'' < ''y'' so that if ''a'' is in ''B'', ''a'' > ''x'' and ''a'' < ''y'' which is impossible by hypothesis), nonempty (''x'' is in ''A'' and ''y'' is in ''B'') and

open Open or OPEN may refer to: Music * Open (band), Australian pop/rock band * The Open (band), English indie rock band * ''Open'' (Blues Image album), 1969 * ''Open'' (Gerd Dudek, Buschi Niebergall, and Edward Vesala album), 1979 * ''Open'' (Go ...

(in the order topology), and their union is ''X''. This contradicts the connectedness of ''X''. Now we prove the least upper bound property. If ''C'' is a subset of ''X'' that is bounded above and has no least upper bound, let ''D'' be the union of all open rays of the form (''b'', +∞) where b is an upper bound for ''C''. Then ''D'' is open (since it is the union of open sets), and closed (if ''a'' is not in ''D'', then ''a'' < ''b'' for all upper bounds ''b'' of ''C'' so that we may choose ''q'' > ''a'' such that ''q'' is in ''C'' (if no such ''q'' exists, ''a'' is the least upper bound of ''C''), then an

containing ''a'' may be chosen that doesn't intersect ''D''). Since ''D'' is nonempty (there is more than one upper bound of ''D'' for if there was exactly one upper bound ''s'', ''s'' would be the least upper bound. Then if ''b''₁ and ''b''₂ are two upper bounds of ''D'' with ''b''₁ < ''b''₂, ''b''₂ will belong to ''D''), ''D'' and its complement together form a separation on ''X''. This contradicts the connectedness of ''X''.

Applications of the theorem

# Since the ordered set ''A'' = (−∞, 0) U (0,+∞) is not a linear continuum, it is disconnected. # By applying the theorem just proved, the fact that R is connected follows. In fact any interval (or ray) in R is also connected. # The set of integers is not a linear continuum and therefore cannot be connected. # In fact, if an ordered set in the order topology is a linear continuum, it must be connected. Since any interval in this set is also a linear continuum, it follows that this space is locally connected since it has a basis consisting entirely of connected sets. # For an example of a

topological space In mathematics, a topological space is, roughly speaking, a Geometry, geometrical space in which Closeness (mathematics), closeness is defined but cannot necessarily be measured by a numeric Distance (mathematics), distance. More specifically, a to ...

that is a linear continuum, see long line.

References

{{reflist Topology Order theory Articles containing proofs

Examples

Non-examples

Topological properties

Applications of the theorem

See also

References