MenuExplore
Enter the information you are looking forSearch
Sat, 08 Feb, 2025
XXX oC
NiNa
Choose a language
  • Home
  • Astrology
  • Wikipedia

    Uniqueness quantification

    Author: www.NiNa.Az
    Feb 05, 2025 / 06:12

    This article needs additional citations for verification Please help improve this article by adding citations to reliabl

    Uniqueness quantification
    Uniqueness quantification
    Uniqueness quantification
    www.NiNa.Azhttps://www.english.nina.az/author.html

    This article needs additional citations for verification. Please help improve this article by adding citations to reliable sources. Unsourced material may be challenged and removed.
    Find sources: "Uniqueness quantification" – news · newspapers · books · scholar · JSTOR     (November 2024) (Learn how and when to remove this message)

    In mathematics and logic, the term "uniqueness" refers to the property of being the one and only object satisfying a certain condition. This sort of quantification is known as uniqueness quantification or unique existential quantification, and is often denoted with the symbols "∃!" or "∃=1".

    For example, the formal statement

    ∃!n∈N(n−2=4){\displaystyle \exists !n\in \mathbb {N} \,(n-2=4)}{\displaystyle \exists !n\in \mathbb {N} \,(n-2=4)}

    may be read as "there is exactly one natural number n{\displaystyle n}{\displaystyle n} such that n−2=4{\displaystyle n-2=4}{\displaystyle n-2=4}".

    Proving uniqueness

    The most common technique to prove the unique existence of an object is to first prove the existence of the entity with the desired condition, and then to prove that any two such entities (say, a{\displaystyle a}image and b{\displaystyle b}image) must be equal to each other (i.e. a=b{\displaystyle a=b}image).

    For example, to show that the equation x+2=5{\displaystyle x+2=5}image has exactly one solution, one would first start by establishing that at least one solution exists, namely 3; the proof of this part is simply the verification that the equation below holds:

    3+2=5.{\displaystyle 3+2=5.}image

    To establish the uniqueness of the solution, one would proceed by assuming that there are two solutions, namely a{\displaystyle a}image and b{\displaystyle b}image, satisfying x+2=5{\displaystyle x+2=5}image. That is,

    a+2=5 and b+2=5.{\displaystyle a+2=5{\text{ and }}b+2=5.}image

    Then since equality is a transitive relation,

    a+2=b+2.{\displaystyle a+2=b+2.}image

    Subtracting 2 from both sides then yields

    a=b.{\displaystyle a=b.}image

    which completes the proof that 3 is the unique solution of x+2=5{\displaystyle x+2=5}image.

    In general, both existence (there exists at least one object) and uniqueness (there exists at most one object) must be proven, in order to conclude that there exists exactly one object satisfying a said condition.

    An alternative way to prove uniqueness is to prove that there exists an object a{\displaystyle a}image satisfying the condition, and then to prove that every object satisfying the condition must be equal to a{\displaystyle a}image.

    Reduction to ordinary existential and universal quantification

    Uniqueness quantification can be expressed in terms of the existential and universal quantifiers of predicate logic, by defining the formula ∃!xP(x){\displaystyle \exists !xP(x)}image to mean

    ∃x(P(x)∧¬∃y(P(y)∧y≠x)),{\displaystyle \exists x\,(P(x)\,\wedge \neg \exists y\,(P(y)\wedge y\neq x)),}image

    which is logically equivalent to

    ∃x(P(x)∧∀y(P(y)→y=x)).{\displaystyle \exists x\,(P(x)\wedge \forall y\,(P(y)\to y=x)).}image

    An equivalent definition that separates the notions of existence and uniqueness into two clauses, at the expense of brevity, is

    ∃xP(x)∧∀y∀z[(P(y)∧P(z))→y=z].{\displaystyle \exists x\,P(x)\wedge \forall y\,\forall z\,[(P(y)\wedge P(z))\to y=z].}image

    Another equivalent definition, which has the advantage of brevity, is

    ∃x∀y(P(y)↔y=x).{\displaystyle \exists x\,\forall y\,(P(y)\leftrightarrow y=x).}image

    Generalizations

    The uniqueness quantification can be generalized into counting quantification (or numerical quantification). This includes both quantification of the form "exactly k objects exist such that …" as well as "infinitely many objects exist such that …" and "only finitely many objects exist such that…". The first of these forms is expressible using ordinary quantifiers, but the latter two cannot be expressed in ordinary first-order logic.

    Uniqueness depends on a notion of equality. Loosening this to a coarser equivalence relation yields quantification of uniqueness up to that equivalence (under this framework, regular uniqueness is "uniqueness up to equality"). For example, many concepts in category theory are defined to be unique up to isomorphism.

    The exclamation mark !{\displaystyle !}image can be also used as a separate quantification symbol, so (∃!x.P(x))↔((∃x.P(x))∧(!x.P(x))){\displaystyle (\exists !x.P(x))\leftrightarrow ((\exists x.P(x))\land (!x.P(x)))}image, where (!x.P(x)):=(∀a∀b.P(a)∧P(b)→a=b){\displaystyle (!x.P(x)):=(\forall a\forall b.P(a)\land P(b)\rightarrow a=b)}image. E.g. it can be safely used in the replacement axiom, instead of ∃!{\displaystyle \exists !}image.

    See also

    • Essentially unique
    • One-hot
    • Singleton (mathematics)
    • Uniqueness theorem

    References

    1. Weisstein, Eric W. "Uniqueness Theorem". mathworld.wolfram.com. Retrieved 2019-12-15.
    2. "2.5 Uniqueness Arguments". www.whitman.edu. Retrieved 2019-12-15.
    3. Helman, Glen (August 1, 2013). "Numerical quantification" (PDF). persweb.wabash.edu. Retrieved 2019-12-14.
    4. This is a consequence of the compactness theorem.

    Bibliography

    • Kleene, Stephen (1952). Introduction to Metamathematics. Ishi Press International. p. 199.
    • Andrews, Peter B. (2002). An introduction to mathematical logic and type theory to truth through proof (2. ed.). Dordrecht: Kluwer Acad. Publ. p. 233. ISBN 1-4020-0763-9.

    This article needs additional citations for verification Please help improve this article by adding citations to reliable sources Unsourced material may be challenged and removed Find sources Uniqueness quantification news newspapers books scholar JSTOR November 2024 Learn how and when to remove this message In mathematics and logic the term uniqueness refers to the property of being the one and only object satisfying a certain condition This sort of quantification is known as uniqueness quantification or unique existential quantification and is often denoted with the symbols or 1 For example the formal statement n N n 2 4 displaystyle exists n in mathbb N n 2 4 may be read as there is exactly one natural number n displaystyle n such that n 2 4 displaystyle n 2 4 Proving uniquenessThe most common technique to prove the unique existence of an object is to first prove the existence of the entity with the desired condition and then to prove that any two such entities say a displaystyle a and b displaystyle b must be equal to each other i e a b displaystyle a b For example to show that the equation x 2 5 displaystyle x 2 5 has exactly one solution one would first start by establishing that at least one solution exists namely 3 the proof of this part is simply the verification that the equation below holds 3 2 5 displaystyle 3 2 5 To establish the uniqueness of the solution one would proceed by assuming that there are two solutions namely a displaystyle a and b displaystyle b satisfying x 2 5 displaystyle x 2 5 That is a 2 5 and b 2 5 displaystyle a 2 5 text and b 2 5 Then since equality is a transitive relation a 2 b 2 displaystyle a 2 b 2 Subtracting 2 from both sides then yields a b displaystyle a b which completes the proof that 3 is the unique solution of x 2 5 displaystyle x 2 5 In general both existence there exists at least one object and uniqueness there exists at most one object must be proven in order to conclude that there exists exactly one object satisfying a said condition An alternative way to prove uniqueness is to prove that there exists an object a displaystyle a satisfying the condition and then to prove that every object satisfying the condition must be equal to a displaystyle a Reduction to ordinary existential and universal quantificationUniqueness quantification can be expressed in terms of the existential and universal quantifiers of predicate logic by defining the formula xP x displaystyle exists xP x to mean x P x y P y y x displaystyle exists x P x wedge neg exists y P y wedge y neq x which is logically equivalent to x P x y P y y x displaystyle exists x P x wedge forall y P y to y x An equivalent definition that separates the notions of existence and uniqueness into two clauses at the expense of brevity is xP x y z P y P z y z displaystyle exists x P x wedge forall y forall z P y wedge P z to y z Another equivalent definition which has the advantage of brevity is x y P y y x displaystyle exists x forall y P y leftrightarrow y x GeneralizationsThe uniqueness quantification can be generalized into counting quantification or numerical quantification This includes both quantification of the form exactly k objects exist such that as well as infinitely many objects exist such that and only finitely many objects exist such that The first of these forms is expressible using ordinary quantifiers but the latter two cannot be expressed in ordinary first order logic Uniqueness depends on a notion of equality Loosening this to a coarser equivalence relation yields quantification of uniqueness up to that equivalence under this framework regular uniqueness is uniqueness up to equality For example many concepts in category theory are defined to be unique up to isomorphism The exclamation mark displaystyle can be also used as a separate quantification symbol so x P x x P x x P x displaystyle exists x P x leftrightarrow exists x P x land x P x where x P x a b P a P b a b displaystyle x P x forall a forall b P a land P b rightarrow a b E g it can be safely used in the replacement axiom instead of displaystyle exists See alsoEssentially unique One hot Singleton mathematics Uniqueness theoremReferencesWeisstein Eric W Uniqueness Theorem mathworld wolfram com Retrieved 2019 12 15 2 5 Uniqueness Arguments www whitman edu Retrieved 2019 12 15 Helman Glen August 1 2013 Numerical quantification PDF persweb wabash edu Retrieved 2019 12 14 This is a consequence of the compactness theorem BibliographyKleene Stephen 1952 Introduction to Metamathematics Ishi Press International p 199 Andrews Peter B 2002 An introduction to mathematical logic and type theory to truth through proof 2 ed Dordrecht Kluwer Acad Publ p 233 ISBN 1 4020 0763 9

    rec-icon Recommended Topics
    Share this article
    • Wikipedia
    Read the free encyclopedia and learn everything...
    See more
    Read the free encyclopedia. All information in Wikipedia is available. No payment required.
    Home / Wikipedia / Uniqueness quantification
    See less
    Share this article on
    Share
    Copy
    [

    Most Popular

    ]

    Horoscopes

    Horoscopes
    NiNa
    • ASTROLOGY
    • Horoscopes
    • WIKIPEDIA
    • Choose a language
    • Contact Us
    © 2019 nina.az
    XXX 0C
    Saturday, 08 February, 2025
    • Home
    • Astrology
    • Wikipedia
    • Astrology
      • Horoscopes
    • Choose a language
    • Contact Us
    © 2019 nina.az - All rights reserved.
    Copyright: Dadash Mammadov
    Follow Us On
    • HomeHomePageHome