“Least-upper-bound property”的意思、由来-开放百科全书

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Least-upper-bound property

释义

Statement of the property
Statement for real numbers Generalization to ordered sets
Proof
Logical status Proof using Cauchy sequences
Applications
Intermediate value theorem Bolzano–Weierstrass theorem Extreme value theorem Heine–Borel theorem
History
See also
Notes
References

In mathematics, the least-upper-bound property (sometimes the completeness or supremum property or l.u.b)^[1] is a fundamental property of the real numbers and certain other ordered sets. A set {{math|X}} has the least-upper-bound property if and only if every non-empty subset of {{math|X}} with an upper bound has a least upper bound (supremum) in {{math|X}}.

The least-upper-bound property is one form of the completeness axiom for the real numbers, and is sometimes referred to as Dedekind completeness.^[2] It can be used to prove many of the fundamental results of real analysis, such as the intermediate value theorem, the Bolzano–Weierstrass theorem, the extreme value theorem, and the Heine–Borel theorem. It is usually taken as an axiom in synthetic constructions of the real numbers (see least upper bound axiom), and it is also intimately related to the construction of the real numbers using Dedekind cuts.

In order theory, this property can be generalized to a notion of completeness for any partially ordered set. A linearly ordered set that is dense and has the least upper bound property is called a linear continuum.

Statement of the property

Statement for real numbers

Let {{math|S}} be a non-empty set of real numbers.

A real number {{math|x}} is called an upper bound for {{math|S}} if {{math|x ≥ s}} for all {{math|s ∈ S}}.
A real number {{math|x}} is the least upper bound (or supremum) for {{math|S}} if {{math|x}} is an upper bound for {{math|S}} and {{math|x ≤ y}} for every upper bound {{math|y}} of {{math|S}}.

The least-upper-bound property states that any non-empty set of real numbers that has an upper bound must have a least upper bound in real numbers.

Generalization to ordered sets

More generally, one may define upper bound and least upper bound for any subset of a partially ordered set {{math|X}}, with “real number” replaced by “element of {{math|X}}”. In this case, we say that {{math|X}} has the least-upper-bound property if every non-empty subset of {{math|X}} with an upper bound has a least upper bound.

For example, the set {{math|Q}} of rational numbers does not have the least-upper-bound property under the usual order. For instance, the set

has an upper bound in {{math|Q}}, but does not have a least upper bound in {{math|Q}} (since the square root of two is irrational). The construction of the real numbers using Dedekind cuts takes advantage of this failure by defining the irrational numbers as the least upper bounds of certain subsets of the rationals.

Proof

Logical status

The least-upper-bound property is equivalent to other forms of the completeness axiom, such as the convergence of Cauchy sequences or the nested intervals theorem. The logical status of the property depends on the construction of the real numbers used: in the synthetic approach, the property is usually taken as an axiom for the real numbers (see least upper bound axiom); in a constructive approach, the property must be proved as a theorem, either directly from the construction or as a consequence of some other form of completeness.

Proof using Cauchy sequences

It is possible to prove the least-upper-bound property using the assumption that every Cauchy sequence of real numbers converges. Let {{math|S}} be a nonempty set of real numbers, and suppose that {{math|S}} has an upper bound {{math|B₁}}. Since {{math|S}} is nonempty, there exists a real number {{math|A₁}} that is not an upper bound for {{math|S}}. Define sequences {{math|A₁, A₂, A₃, ...}} and {{math|B₁, B₂, B₃, ...}} recursively as follows:

Check whether {{math|(A_n + B_n) ⁄ 2}} is an upper bound for {{math|S}}.
If it is, let {{math|A_n+1 {{=}} A_n}} and let {{math|B_n+1 {{=}} (A_n + B_n) ⁄ 2}}.
Otherwise there must be an element {{math|s}} in {{math|S}} so that {{math|s>(A_n + B_n) ⁄ 2}}. Let {{math|A_n+1 {{=}} s}} and let {{math|B_n+1 {{=}} B_n}}.

Then {{math|A₁ ≤ A₂ ≤ A₃ ≤ ⋯ ≤ B₃ ≤ B₂ ≤ B₁}} and {{math|{{!}}A_n − B_n{{!}} → 0}} as {{math|n → ∞}}. It follows that both sequences are Cauchy and have the same limit {{math|L}}, which must be the least upper bound for {{math|S}}.

Applications

The least-upper-bound property of {{math|R}} can be used to prove many of the main foundational theorems in real analysis.

Intermediate value theorem

Let {{math|f : [a, b] → R}} be a continuous function, and suppose that {{math|f (a) < 0}} and {{math|f (b) > 0}}. In this case, the intermediate value theorem states that {{math|f}} must have a root in the interval {{math|[a, b]}}. This theorem can proved by considering the set

{{math|S {{=}} {s ∈ [a, b] : f (x) < 0 for all x ≤ s} }}.

That is, {{math|S}} is the initial segment of {{math|[a, b]}} that takes negative values under {{math|f}}. Then {{math|b}} is an upper bound for {{math|S}}, and the least upper bound must be a root of {{math|f}}.

Bolzano–Weierstrass theorem

The Bolzano–Weierstrass theorem for {{math|R}} states that every sequence {{math|x_n}} of real numbers in a closed interval {{math|[a, b]}} must have a convergent subsequence. This theorem can be proved by considering the set

{{math|S {{=}} {s ∈ [a, b] : s ≤ x_n for infinitely many n} }}.

Clearly {{math|b}} is an upper bound for {{math|S}}, so {{math|S}} has a least upper bound {{math|c}}. Then {{math|c}} must be a limit point of the sequence {{math|x_n}}, and it follows that {{math|x_n}} has a subsequence that converges to {{math|c}}.

Extreme value theorem

Let {{math|f : [a, b] → R}} be a continuous function and let {{math|M {{=}} sup f ([a, b])}}, where {{math|M {{=}} ∞}} if {{math|f ([a, b])}} has no upper bound. The extreme value theorem states that {{math|M}} is finite and {{math|f (c) {{=}} M}} for some {{math|c ∈ [a, b]}}. This can be proved by considering the set

{{math|S {{=}} {s ∈ [a, b] : sup f ([s, b]) {{=}} M} }}.

If {{math|c}} is the least upper bound of this set, then it follows from continuity that {{math|f (c) {{=}} M}}.

Heine–Borel theorem

Let {{math|[a, b]}} be a closed interval in {{math|R}}, and let {{math|{U_α} }} be a collection of open sets that covers {{math|[a, b]}}. Then the Heine–Borel theorem states that some finite subcollection of {{math|{U_α} }} covers {{math|[a, b]}} as well. This statement can be proved by considering the set

{{math|S {{=}} {s ∈ [a, b] : [a, s] can be covered by finitely many U_α} }}.

This set must have a least upper bound {{math|c}}. But {{math|c}} is itself an element of some open set {{math|U_α}}, and it follows that {{math|[a, c + δ]}} can be covered by finitely many {{math|U_α}} for some sufficiently small {{math|δ > 0}}. This proves that {{math|c + δ ∈ S}}, and it also yields a contradiction unless {{math|c {{=}} b}}.

History

The importance of the least-upper-bound property was first recognized by Bernard Bolzano in his 1817 paper Rein analytischer Beweis des Lehrsatzes dass zwischen je zwey Werthen, die ein entgegengesetztes Resultat gewäahren, wenigstens eine reelle Wurzel der Gleichung liege.^[3]

Notes

1. ^Bartle and Sherbert (2011) define the "completeness property" and say that it is also called the "supremum property". (p. 39)
2. ^Willard says that an ordered space "X is Dedekind complete if every subset of X having an upper bound has a least upper bound." (pp. 124-5, Problem 17E.)
3. ^{{cite journal | journal = American Mathematical Monthly | title = A Pedagogical History of Compactness | last1 = Raman-Sundström | first1 = Manya | date = August–September 2015 | volume = 122 | issue = 7 | pages = 619–635 | jstor = 10.4169/amer.math.monthly.122.7.619| doi = 10.4169/amer.math.monthly.122.7.619 }}

References

{{cite book |author=Abbott, Stephen |title=Understanding Analysis |series=Undergraduate Texts in Mathematics |isbn=0-387-95060-5 |date=2001 |location=New York |publisher=Springer-Verlag }}
{{cite book

| last = Aliprantis
| first = Charalambos D
| authorlink = Charalambos D. Aliprantis
|author2=Burkinshaw, Owen
| title = Principles of real analysis
| edition = Third
| publisher = Academic
| date = 1998
| pages =
| isbn = 0-12-050257-7
}}

{{cite book |author1=Bartle, Robert G. |author2=Sherbert, Donald R. |title=Introduction to Real Analysis |edition=4 |location=New York |publisher=John Wiley and Sons |date=2011 |isbn=978-0-471-43331-6 |ref=Bartle}}
{{cite book |author=Bressoud, David |title=A Radical Approach to Real Analysis |isbn=0-88385-747-2 |publisher=MAA |date=2007 }}
{{cite book |author=Browder, Andrew |title=Mathematical Analysis: An Introduction |series=Undergraduate Texts in Mathematics |location=New York |publisher=Springer-Verlag |date=1996 |isbn=0-387-94614-4 }}
{{cite book |author1=Dangello, Frank |author2=Seyfried, Michael |title=Introductory Real Analysis |isbn=978-0-395-95933-6 |publisher=Brooks Cole |date=1999 }}
{{cite book |author=Rudin, Walter |title=Principles of Mathematical Analysis |series=Walter Rudin Student Series in Advanced Mathematics |edition=3 |publisher=McGraw–Hill |isbn=978-0-07-054235-8 }}
{{cite book |last=Willard |first=Stephen |title=General Topology |isbn=9780486434797 |origyear=1970|year=2004 |location=Mineola, N.Y. |publisher=Dover Publications }}

3 : Real analysis|Order theory|Articles containing proofs

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