Difference between revisions of "The Integers"

From Department of Mathematics at UTSA
Jump to navigation Jump to search
(Created page with "An '''integer''' (from the Latin ''integer'' meaning "whole"){{efn|''Integer'' 's first literal meaning in Latin is "untouched", from ''in'' ("not...")
 
Line 1: Line 1:
An '''integer''' (from the [[Latin]] [[wikt:integer#Latin|''integer'']] meaning "whole"){{efn|''Integer'' 's first literal meaning in Latin is "untouched", from ''in'' ("not") plus ''tangere'' ("to touch"). "[[wikt:entire|Entire]]" derives from the same origin via the [[French language|French]] word ''[[wikt:entier|entier]]'', which means both ''entire'' and ''integer''.<ref>{{cite book |first=Nick |last=Evans |contribution=A-Quantifiers and Scope |editor-first=Emmon W. |editor-last=Bach |title=Quantification in Natural Languages |isbn=978-0-7923-3352-4 |year=1995 |pages=262 |url=https://books.google.com/books?id=NlQL97qBSZkC |location=Dordrecht, The Netherlands; Boston, MA |publisher=Kluwer Academic Publishers}}</ref>}} is colloquially defined as a [[number]] that can be written without a [[Fraction (mathematics)|fractional component]]. For example, 21, 4, 0, and −2048 are integers, while 9.75, {{sfrac|5|1|2}}, and&nbsp;{{math|{{sqrt|2}}}} are not.
+
An '''integer''' is colloquially defined as a number that can be written without a fractional component. For example, 21, 4, 0, and −2048 are integers, while 9.75, {{sfrac|5|1|2}}, and&nbsp;{{math|{{sqrt|2}}}} are not.
  
The [[Set (mathematics)|set]] of integers consists of zero ({{num|0}}), the positive [[natural number]]s ({{num|1}}, {{num|2}}, {{num|3}},&nbsp;...), also called ''whole numbers'' or ''counting numbers'',<ref name=MathWorld_CountingNumber>{{MathWorld|title=Counting Number|id=CountingNumber}}</ref><ref name=MathWorld_WholeNumber>{{MathWorld|title=Whole Number|id=WholeNumber}}</ref> and their [[additive inverse]]s (the '''negative integers''', i.e., [[−1]], −2, −3,&nbsp;...). The set of integers is often denoted by the [[boldface]] ({{math|'''Z'''}}) or [[blackboard bold]] <math>(\mathbb{Z})</math> letter "Z"—standing originally for the [[German language|German]] word ''[[wikt:Zahlen|Zahlen]]'' ("numbers").<ref>{{Cite web|last=Weisstein|first=Eric W.|title=Integer|url=https://mathworld.wolfram.com/Integer.html|access-date=2020-08-11|website=mathworld.wolfram.com|language=en}}</ref><ref>{{cite web |url=http://jeff560.tripod.com/nth.html |title=Earliest Uses of Symbols of Number Theory |access-date=2010-09-20 |date=2010-08-29 |first=Jeff |last=Miller |archive-url=https://web.archive.org/web/20100131022510/http://jeff560.tripod.com/nth.html |archive-date=2010-01-31 |url-status=dead }}</ref><ref name="Cameron1998">{{cite book |author=Peter Jephson Cameron |title=Introduction to Algebra |url=https://books.google.com/books?id=syYYl-NVM5IC&pg=PA4 |year=1998 |publisher=Oxford University Press |isbn=978-0-19-850195-4 |page=4 |access-date=2016-02-15 |archive-url=https://web.archive.org/web/20161208142220/https://books.google.com/books?id=syYYl-NVM5IC&pg=PA4 |archive-date=2016-12-08 |url-status=live }}</ref>
+
The set of integers consists of zero ({{num|0}}), the positive natural numbers ({{num|1}}, {{num|2}}, {{num|3}},&nbsp;...), also called ''whole numbers'' or ''counting numbers'', and their additive inverses (the '''negative integers''', i.e., −1, −2, −3,&nbsp;...). The set of integers is often denoted by the boldface ({{math|'''Z'''}}) or blackboard bold <math>(\mathbb{Z})</math> letter "Z".
  
<math>\mathbb{Z}</math> is a [[subset]] of the set of all [[Rational number|rational]] numbers <math>\mathbb{Q}</math>, which in turn is a subset of the [[Real number|real]] numbers <math>\mathbb{R}</math>.  Like the natural numbers, <math>\mathbb{Z}</math> is [[Countable set|countably infinite]].
+
<math>\mathbb{Z}</math> is a subset of the set of all rational numbers <math>\mathbb{Q}</math>, which in turn is a subset of the real numbers <math>\mathbb{R}</math>.  Like the natural numbers, <math>\mathbb{Z}</math> is countably infinite.
  
The integers form the smallest [[Group (mathematics)|group]] and the smallest [[ring (mathematics)|ring]] containing the [[natural number]]s. In [[algebraic number theory]], the integers are sometimes qualified as '''rational integers''' to distinguish them from the more general [[algebraic integer]]s. In fact, (rational) integers are algebraic integers that are also [[rational number]]s.
+
The integers form the smallest group and the smallest ring containing the natural numbers. In algebraic number theory, the integers are sometimes qualified as '''rational integers''' to distinguish them from the more general algebraic integers. In fact, (rational) integers are algebraic integers that are also rational numbers.
  
 
==Symbol==
 
==Symbol==
The symbol <math>\mathbb{Z}</math> can be annotated to denote various sets, with varying usage amongst different authors: <math>\mathbb{Z}^+</math>,<math>\mathbb{Z}_+</math> or <math>\mathbb{Z}^{>}</math> for the positive integers, <math>\mathbb{Z}^{0+}</math> or <math>\mathbb{Z}^{\geq}</math> for non-negative integers, and <math>\mathbb{Z}^{\neq}</math> for non-zero integers. Some authors use <math>\mathbb{Z}^{*}</math> for non-zero integers, while others use it for non-negative integers, or for {{math|{–1, 1}{{void}}}}. Additionally, <math>\mathbb{Z}_{p}</math> is used to denote either the set of [[integers modulo n|integers modulo {{math|''p''}}]] (i.e., the set of [[congruence relation|congruence classes]] of integers), or the set of [[p-adic integer|{{math|''p''}}-adic integers]].<ref name=edexcelc1>Keith Pledger and Dave Wilkins, "Edexcel AS and A Level Modular Mathematics: Core Mathematics 1" Pearson 2008</ref><ref>LK Turner, FJ BUdden, D Knighton, "Advanced Mathematics", Book 2, Longman 1975.</ref><ref>{{MathWorld |title=Z^* |id=Z^*}}</ref>
+
The symbol <math>\mathbb{Z}</math> can be annotated to denote various sets, with varying usage amongst different authors: <math>\mathbb{Z}^+</math>,<math>\mathbb{Z}_+</math> or <math>\mathbb{Z}^{>}</math> for the positive integers, <math>\mathbb{Z}^{0+}</math> or <math>\mathbb{Z}^{\geq}</math> for non-negative integers, and <math>\mathbb{Z}^{\neq}</math> for non-zero integers. Some authors use <math>\mathbb{Z}^{*}</math> for non-zero integers, while others use it for non-negative integers, or for {{math|{–1, 1}{{void}}}}. Additionally, <math>\mathbb{Z}_{p}</math> is used to denote either the set of integers modulo {{math|''p''}} (i.e., the set of congruence classes of integers), or the set of {{math|''p''}}-adic integers.
  
 
== Algebraic properties ==
 
== Algebraic properties ==
[[File:Number-line.svg|right|thumb|300px|Integers can be thought of as discrete, equally spaced points on an infinitely long [[number line]]. In the above, non-[[Sign (mathematics)#Terminology for signs|negative]] integers are shown in blue and negative integers in red.]]
+
[[File:Number-line.svg|right|thumb|300px|Integers can be thought of as discrete, equally spaced points on an infinitely long number line. In the above, non-negative integers are shown in blue and negative integers in red.]]
 
{{Ring theory sidebar}}
 
{{Ring theory sidebar}}
  
Like the [[natural numbers]], <math>\mathbb{Z}</math> is [[closure (mathematics)|closed]] under the [[binary operation|operations]] of addition and [[multiplication]], that is, the sum and product of any two integers is an integer. However, with the inclusion of the negative natural numbers (and importantly,&nbsp;{{num|0}}), <math>\mathbb{Z}</math>, unlike the natural numbers, is also closed under [[subtraction]].<ref>{{Cite web|title=Integer {{!}} mathematics|url=https://www.britannica.com/science/integer|access-date=2020-08-11|website=Encyclopedia Britannica|language=en}}</ref>
+
Like the natural numbers, <math>\mathbb{Z}</math> is closed under the operations of addition and multiplication, that is, the sum and product of any two integers is an integer. However, with the inclusion of the negative natural numbers (and importantly,&nbsp;{{num|0}}), <math>\mathbb{Z}</math>, unlike the natural numbers, is also closed under subtraction.
  
The integers form a [[unital ring]] which is the most basic one, in the following sense: for any unital ring, there is a unique [[ring homomorphism]] from the integers into this ring. This [[universal property]], namely to be an [[initial object]] in the [[category of rings]], characterizes the ring&nbsp;<math>\mathbb{Z}</math>.
+
The integers form a unital ring which is the most basic one, in the following sense: for any unital ring, there is a unique ring homomorphism from the integers into this ring. This universal property, namely to be an initial object in the category of rings, characterizes the ring&nbsp;<math>\mathbb{Z}</math>.
  
<math>\mathbb{Z}</math> is not closed under [[division (mathematics)|division]], since the quotient of two integers (e.g.,&nbsp;1 divided by&nbsp;2) need not be an integer. Although the natural numbers are closed under [[exponentiation]], the integers are not (since the result can be a fraction when the exponent is negative).
+
<math>\mathbb{Z}</math> is not closed under division, since the quotient of two integers (e.g.,&nbsp;1 divided by&nbsp;2) need not be an integer. Although the natural numbers are closed under exponentiation, the integers are not (since the result can be a fraction when the exponent is negative).
  
 
The following table lists some of the basic properties of addition and multiplication for any integers {{math|''a''}}, {{math|''b''}} and {{math|''c''}}:
 
The following table lists some of the basic properties of addition and multiplication for any integers {{math|''a''}}, {{math|''b''}} and {{math|''c''}}:
Line 27: Line 27:
 
!scope="col" |Multiplication
 
!scope="col" |Multiplication
 
|-
 
|-
!scope="row" |[[Closure (mathematics)|Closure]]:
+
!scope="row" |Closure:
 
|{{math|''a'' + ''b''}}{{pad|1em}}is an integer
 
|{{math|''a'' + ''b''}}{{pad|1em}}is an integer
 
|{{math|''a'' × ''b''}}{{pad|1em}}is an integer
 
|{{math|''a'' × ''b''}}{{pad|1em}}is an integer
 
|-
 
|-
!scope="row"|[[Associativity]]:
+
!scope="row"|Associativity:
 
|{{math|''a'' + (''b'' + ''c'') {{=}} (''a'' + ''b'') + ''c''}}
 
|{{math|''a'' + (''b'' + ''c'') {{=}} (''a'' + ''b'') + ''c''}}
 
|{{math|''a'' × (''b'' × ''c'') {{=}} (''a'' × ''b'') × ''c''}}
 
|{{math|''a'' × (''b'' × ''c'') {{=}} (''a'' × ''b'') × ''c''}}
 
|-
 
|-
!scope="row" |[[Commutativity]]:
+
!scope="row" |Commutativity:
 
|{{math|''a'' + ''b'' {{=}} ''b'' + ''a''}}
 
|{{math|''a'' + ''b'' {{=}} ''b'' + ''a''}}
 
|{{math|''a'' × ''b'' {{=}} ''b'' × ''a''}}
 
|{{math|''a'' × ''b'' {{=}} ''b'' × ''a''}}
 
|-
 
|-
!scope="row" |Existence of an [[identity element]]:
+
!scope="row" |Existence of an identity element:
 
|{{math|''a'' + 0 {{=}} ''a''}}
 
|{{math|''a'' + 0 {{=}} ''a''}}
 
|{{math|''a'' × 1 {{=}} ''a''}}
 
|{{math|''a'' × 1 {{=}} ''a''}}
 
|-
 
|-
!scope="row" |Existence of [[inverse element]]s:
+
!scope="row" |Existence of inverse elements:
 
|{{math|''a'' + (−''a'') {{=}} 0}}
 
|{{math|''a'' + (−''a'') {{=}} 0}}
|The only invertible integers (called [[Unit (ring theory)|units]]) are {{math|−1}} and&nbsp;{{math|1}}.
+
|The only invertible integers (called units) are {{math|−1}} and&nbsp;{{math|1}}.
 
|-
 
|-
!scope="row" |[[Distributivity]]:
+
!scope="row" |Distributivity:
 
|colspan=2 align=center |{{math|''a'' × (''b'' + ''c'') {{=}} (''a'' × ''b'') + (''a'' × ''c'')}}{{pad|1em}}and{{pad|1em}}{{math|(''a'' + ''b'') × ''c'' {{=}} (''a'' × ''c'') + (''b'' × ''c'')}}
 
|colspan=2 align=center |{{math|''a'' × (''b'' + ''c'') {{=}} (''a'' × ''b'') + (''a'' × ''c'')}}{{pad|1em}}and{{pad|1em}}{{math|(''a'' + ''b'') × ''c'' {{=}} (''a'' × ''c'') + (''b'' × ''c'')}}
 
|-
 
|-
!scope="row" |No [[zero divisor]]s:
+
!scope="row" |No zero divisors:
 
| || | If {{math|''a'' × ''b'' {{=}} 0}}, then {{math|''a'' {{=}} 0}} or {{math|''b'' {{=}} 0}} (or both)
 
| || | If {{math|''a'' × ''b'' {{=}} 0}}, then {{math|''a'' {{=}} 0}} or {{math|''b'' {{=}} 0}} (or both)
 
|}
 
|}
  
The first five properties listed above for addition say that <math>\mathbb{Z}</math>, under addition, is an [[abelian group]]. It is also a [[cyclic group]], since every non-zero integer can be written as a finite sum {{nowrap|1 + 1 + ... + 1}} or {{nowrap|(−1) + (−1) + ... + (−1)}}. In fact, <math>\mathbb{Z}</math> under addition is the ''only'' infinite cyclic group—in the sense that any infinite cyclic group is [[group isomorphism|isomorphic]] to <math>\mathbb{Z}</math>.
+
The first five properties listed above for addition say that <math>\mathbb{Z}</math>, under addition, is an abelian group. It is also a cyclic group, since every non-zero integer can be written as a finite sum {{nowrap|1 + 1 + ... + 1}} or {{nowrap|(−1) + (−1) + ... + (−1)}}. In fact, <math>\mathbb{Z}</math> under addition is the ''only'' infinite cyclic group—in the sense that any infinite cyclic group is isomorphic to <math>\mathbb{Z}</math>.
  
The first four properties listed above for multiplication say that <math>\mathbb{Z}</math> under multiplication is a [[commutative monoid]]. However, not every integer has a multiplicative inverse (as is the case of the number 2), which means that <math>\mathbb{Z}</math> under multiplication is not a group.
+
The first four properties listed above for multiplication say that <math>\mathbb{Z}</math> under multiplication is a commutative monoid. However, not every integer has a multiplicative inverse (as is the case of the number 2), which means that <math>\mathbb{Z}</math> under multiplication is not a group.
  
All the rules from the above property table (except for the last), when taken together, say that <math>\mathbb{Z}</math> together with addition and multiplication is a [[commutative ring]] with [[multiplicative identity|unity]]. It is the prototype of all objects of such [[algebraic structure]]. Only those [[equality (mathematics)|equalities]] of [[algebraic expression|expressions]] are true in&nbsp;<math>\mathbb{Z}</math> [[for all]] values of variables, which are true in any unital commutative ring. Certain non-zero integers map to [[additive identity|zero]] in certain rings.
+
All the rules from the above property table (except for the last), when taken together, say that <math>\mathbb{Z}</math> together with addition and multiplication is a commutative ring with unity. It is the prototype of all objects of such algebraic structure. Only those equalities of expressions are true in&nbsp;<math>\mathbb{Z}</math> for all values of variables, which are true in any unital commutative ring. Certain non-zero integers map to zero in certain rings.
  
The lack of [[zero divisor]]s in the integers (last property in the table) means that the commutative ring&nbsp;<math>\mathbb{Z}</math> is an [[integral domain]].
+
The lack of zero divisors in the integers (last property in the table) means that the commutative ring&nbsp;<math>\mathbb{Z}</math> is an integral domain.
  
The lack of multiplicative inverses, which is equivalent to the fact that <math>\mathbb{Z}</math> is not closed under division, means that <math>\mathbb{Z}</math> is ''not'' a [[field (mathematics)|field]]. The smallest field containing the integers as a [[subring]] is the field of [[rational number]]s. The process of constructing the rationals from the integers can be mimicked to form the [[field of fractions]] of any integral domain. And back, starting from an [[algebraic number field]] (an extension of rational numbers), its [[ring of integers]] can be extracted, which includes <math>\mathbb{Z}</math> as its [[subring]].
+
The lack of multiplicative inverses, which is equivalent to the fact that <math>\mathbb{Z}</math> is not closed under division, means that <math>\mathbb{Z}</math> is ''not'' a field. The smallest field containing the integers as a subring is the field of rational numbers. The process of constructing the rationals from the integers can be mimicked to form the field of fractions of any integral domain. And back, starting from an algebraic number field (an extension of rational numbers), its ring of integers can be extracted, which includes <math>\mathbb{Z}</math> as its subring.
  
Although ordinary division is not defined on <math>\mathbb{Z}</math>, the division "with remainder" is defined on them. It is called [[Euclidean division]], and possesses the following important property: given two integers {{math|''a''}} and {{math|''b''}} with {{math|''b'' ≠ 0}}, there exist unique integers {{math|''q''}} and {{math|''r''}} such that {{math|''a'' {{=}} ''q'' × ''b'' + ''r''}} and {{math|0 ≤ ''r'' <  {{!}}''b''{{!}}}}, where {{math|{{!}}''b''{{!}}}} denotes the [[absolute value]] of {{math|''b''}}. The integer {{math|''q''}} is called the ''quotient'' and {{math|''r''}} is called the ''[[remainder]]'' of the division of {{math|''a''}} by {{math|''b''}}. The [[Euclidean algorithm]] for computing [[greatest common divisor]]s works by a sequence of Euclidean divisions.
+
Although ordinary division is not defined on <math>\mathbb{Z}</math>, the division "with remainder" is defined on them. It is called Euclidean division, and possesses the following important property: given two integers {{math|''a''}} and {{math|''b''}} with {{math|''b'' ≠ 0}}, there exist unique integers {{math|''q''}} and {{math|''r''}} such that {{math|''a'' {{=}} ''q'' × ''b'' + ''r''}} and {{math|0 ≤ ''r'' <  {{!}}''b''{{!}}}}, where {{math|{{!}}''b''{{!}}}} denotes the absolute value of {{math|''b''}}. The integer {{math|''q''}} is called the ''quotient'' and {{math|''r''}} is called the ''remainder'' of the division of {{math|''a''}} by {{math|''b''}}. The Euclidean algorithm for computing greatest common divisors works by a sequence of Euclidean divisions.
  
The above says that <math>\mathbb{Z}</math> is a [[Euclidean domain]]. This implies that <math>\mathbb{Z}</math> is a [[principal ideal domain]], and any positive integer can be written as the products of [[prime number|primes]] in an [[essentially unique]] way.<ref>{{cite book |last=Serge |first=Lang |author-link=Serge Lang |title=Algebra |edition=3rd |publisher=Addison-Wesley |year=1993 |isbn=978-0-201-55540-0 |pages=86–87}}</ref> This is the [[fundamental theorem of arithmetic]].
+
The above says that <math>\mathbb{Z}</math> is a Euclidean domain. This implies that <math>\mathbb{Z}</math> is a principal ideal domain, and any positive integer can be written as the products of primes in an essentially unique way. This is the fundamental theorem of arithmetic.
  
 
==Order-theoretic properties==
 
==Order-theoretic properties==
<math>\mathbb{Z}</math> is a [[total order|totally ordered set]] without [[upper and lower bounds|upper or lower bound]]. The ordering of <math>\mathbb{Z}</math> is given by:
+
<math>\mathbb{Z}</math> is a totally ordered set without upper or lower bound. The ordering of <math>\mathbb{Z}</math> is given by:
 
{{math|:... −3 < −2 < −1 < 0 < 1 < 2 < 3 < ...}}
 
{{math|:... −3 < −2 < −1 < 0 < 1 < 2 < 3 < ...}}
An integer is ''positive'' if it is greater than [[0|zero]], and ''negative'' if it is less than zero. Zero is defined as neither negative nor positive.
+
An integer is ''positive'' if it is greater than zero, and ''negative'' if it is less than zero. Zero is defined as neither negative nor positive.
  
 
The ordering of integers is compatible with the algebraic operations in the following way:
 
The ordering of integers is compatible with the algebraic operations in the following way:
Line 77: Line 77:
 
# if {{math|''a'' < ''b''}} and {{math|0 < ''c''}}, then {{math|''ac'' < ''bc''}}.
 
# if {{math|''a'' < ''b''}} and {{math|0 < ''c''}}, then {{math|''ac'' < ''bc''}}.
  
Thus it follows that <math>\mathbb{Z}</math> together with the above ordering is an [[ordered ring]].
+
Thus it follows that <math>\mathbb{Z}</math> together with the above ordering is an ordered ring.
  
The integers are the only nontrivial [[totally ordered]] [[abelian group]] whose positive elements are [[well-ordered]].<ref>{{cite book |title=Modern Algebra |series=Dover Books on Mathematics |first=Seth |last=Warner |publisher=Courier Corporation |year=2012 |isbn=978-0-486-13709-4 |at=Theorem 20.14, p.&nbsp;185 |url=https://books.google.com/books?id=TqHDAgAAQBAJ&pg=PA185 |access-date=2015-04-29 |archive-url=https://web.archive.org/web/20150906083836/https://books.google.com/books?id=TqHDAgAAQBAJ&pg=PA185|archive-date=2015-09-06 |url-status=live}}.</ref> This is equivalent to the statement that any [[Noetherian ring|Noetherian]] [[valuation ring]] is either a [[Field (mathematics)|field]]—or a [[discrete valuation ring]].
+
The integers are the only nontrivial totally ordered abelian group whose positive elements are well-ordered. This is equivalent to the statement that any Noetherian valuation ring is either a field—or a discrete valuation ring.
  
 
==Construction==
 
==Construction==
 
[[File:Relative numbers representation.svg|thumb|alt=Representation of equivalence classes for the numbers −5 to 5
 
[[File:Relative numbers representation.svg|thumb|alt=Representation of equivalence classes for the numbers −5 to 5
|Red points represent ordered pairs of [[natural number]]s. Linked red points are equivalence classes representing the blue integers at the end of the line.|upright=1.5]]
+
|Red points represent ordered pairs of natural numbers. Linked red points are equivalence classes representing the blue integers at the end of the line.|upright=1.5]]
In elementary school teaching, integers are often intuitively defined as the (positive) natural numbers, [[zero]], and the negations of the natural numbers. However, this style of definition leads to many different cases (each arithmetic operation needs to be defined on each combination of types of integer) and makes it tedious to prove that integers obey the various laws of arithmetic.<ref>{{cite book |title=Number Systems and the Foundations of Analysis |series=Dover Books on Mathematics |first=Elliott |last=Mendelson |publisher=Courier Dover Publications |year=2008 |isbn=978-0-486-45792-5 |page=86 |url=https://books.google.com/books?id=3domViIV7HMC&pg=PA86 |access-date=2016-02-15 |archive-url=https://web.archive.org/web/20161208233040/https://books.google.com/books?id=3domViIV7HMC&pg=PA86 |archive-date=2016-12-08|url-status=live}}.</ref> Therefore, in modern set-theoretic mathematics, a more abstract construction<ref>Ivorra Castillo: ''Álgebra''</ref> allowing one to define arithmetical operations without any case distinction is often used instead.<ref>{{cite book |title=Learning to Teach Number: A Handbook for Students and Teachers in the Primary School |series=The Stanley Thornes Teaching Primary Maths Series |first=Len |last=Frobisher |publisher=Nelson Thornes |year=1999 |isbn=978-0-7487-3515-0 |page=126 |url=https://books.google.com/books?id=KwJQIt4jQHUC&pg=PA126 |access-date=2016-02-15 |archive-url=https://web.archive.org/web/20161208121843/https://books.google.com/books?id=KwJQIt4jQHUC&pg=PA126 |archive-date=2016-12-08 |url-status=live}}.</ref> The integers can thus be formally constructed as the [[equivalence class]]es of [[ordered pair]]s of [[natural number]]s {{math|(''a'',''b'')}}.<ref name="Campbell-1970-p83">{{cite book |author=Campbell, Howard E. |title=The structure of arithmetic |publisher=Appleton-Century-Crofts |year=1970 |isbn=978-0-390-16895-5 |page=[https://archive.org/details/structureofarith00camp/page/83 83] |url-access=registration |url=https://archive.org/details/structureofarith00camp/page/83 }}</ref>
+
In elementary school teaching, integers are often intuitively defined as the (positive) natural numbers, zero, and the negations of the natural numbers. However, this style of definition leads to many different cases (each arithmetic operation needs to be defined on each combination of types of integer) and makes it tedious to prove that integers obey the various laws of arithmetic.<ref>{{cite book |title=Number Systems and the Foundations of Analysis |series=Dover Books on Mathematics |first=Elliott |last=Mendelson |publisher=Courier Dover Publications |year=2008 |isbn=978-0-486-45792-5 |page=86 |url=https://books.google.com/books?id=3domViIV7HMC&pg=PA86 |access-date=2016-02-15 |archive-url=https://web.archive.org/web/20161208233040/https://books.google.com/books?id=3domViIV7HMC&pg=PA86 |archive-date=2016-12-08|url-status=live}}.</ref> Therefore, in modern set-theoretic mathematics, a more abstract construction<ref>Ivorra Castillo: ''Álgebra''</ref> allowing one to define arithmetical operations without any case distinction is often used instead.<ref>{{cite book |title=Learning to Teach Number: A Handbook for Students and Teachers in the Primary School |series=The Stanley Thornes Teaching Primary Maths Series |first=Len |last=Frobisher |publisher=Nelson Thornes |year=1999 |isbn=978-0-7487-3515-0 |page=126 |url=https://books.google.com/books?id=KwJQIt4jQHUC&pg=PA126 |access-date=2016-02-15 |archive-url=https://web.archive.org/web/20161208121843/https://books.google.com/books?id=KwJQIt4jQHUC&pg=PA126 |archive-date=2016-12-08 |url-status=live}}.</ref> The integers can thus be formally constructed as the equivalence classes of ordered pairs of natural numbers {{math|(''a'',''b'')}}.
  
The intuition is that {{math|(''a'',''b'')}} stands for the result of subtracting {{math|''b''}} from {{math|''a''}}.<ref name="Campbell-1970-p83"/> To confirm our expectation that {{nowrap|1 − 2}} and {{nowrap|4 − 5}} denote the same number, we define an [[equivalence relation]] {{math|~}} on these pairs with the following rule:
+
The intuition is that {{math|(''a'',''b'')}} stands for the result of subtracting {{math|''b''}} from {{math|''a''}}. To confirm our expectation that {{nowrap|1 − 2}} and {{nowrap|4 − 5}} denote the same number, we define an equivalence relation {{math|~}} on these pairs with the following rule:
 
:<math>(a,b) \sim (c,d) </math>
 
:<math>(a,b) \sim (c,d) </math>
 
precisely when
 
precisely when
 
:<math>a + d = b + c. </math>
 
:<math>a + d = b + c. </math>
  
Addition and multiplication of integers can be defined in terms of the equivalent operations on the natural numbers;<ref name="Campbell-1970-p83"/> by using {{math|[(''a'',''b'')]}} to denote the equivalence class having {{math|(''a'',''b'')}} as a member, one has:
+
Addition and multiplication of integers can be defined in terms of the equivalent operations on the natural numbers; by using {{math|[(''a'',''b'')]}} to denote the equivalence class having {{math|(''a'',''b'')}} as a member, one has:
 
:<math>[(a,b)] + [(c,d)] := [(a+c,b+d)].</math>
 
:<math>[(a,b)] + [(c,d)] := [(a+c,b+d)].</math>
 
:<math>[(a,b)]\cdot[(c,d)] := [(ac+bd,ad+bc)].</math>
 
:<math>[(a,b)]\cdot[(c,d)] := [(ac+bd,ad+bc)].</math>
Line 102: Line 102:
  
 
The standard ordering on the integers is given by:
 
The standard ordering on the integers is given by:
:<math>[(a,b)] < [(c,d)]</math> [[if and only if]] <math>a+d < b+c.</math>
+
:<math>[(a,b)] < [(c,d)]</math> if and only if <math>a+d < b+c.</math>
  
 
It is easily verified that these definitions are independent of the choice of representatives of the equivalence classes.
 
It is easily verified that these definitions are independent of the choice of representatives of the equivalence classes.
  
Every equivalence class has a unique member that is of the form {{math|(''n'',0)}} or {{math|(0,''n'')}} (or both at once). The natural number {{math|''n''}} is identified with the class {{math|[(''n'',0)]}} (i.e., the natural numbers are [[embedding|embedded]] into the integers by map sending {{math|''n''}} to {{math|[(''n'',0)]}}), and the class {{math|[(0,''n'')]}} is denoted {{math|−''n''}} (this covers all remaining classes, and gives the class {{math|[(0,0)]}} a second time since {{math|−0 {{=}} 0.}}
+
Every equivalence class has a unique member that is of the form {{math|(''n'',0)}} or {{math|(0,''n'')}} (or both at once). The natural number {{math|''n''}} is identified with the class {{math|[(''n'',0)]}} (i.e., the natural numbers are embedded into the integers by map sending {{math|''n''}} to {{math|[(''n'',0)]}}), and the class {{math|[(0,''n'')]}} is denoted {{math|−''n''}} (this covers all remaining classes, and gives the class {{math|[(0,0)]}} a second time since {{math|−0 {{=}} 0.}}
  
 
Thus, {{math|[(''a'',''b'')]}} is denoted by
 
Thus, {{math|[(''a'',''b'')]}} is denoted by
Line 113: Line 113:
 
If the natural numbers are identified with the corresponding integers (using the embedding mentioned above), this convention creates no ambiguity.
 
If the natural numbers are identified with the corresponding integers (using the embedding mentioned above), this convention creates no ambiguity.
  
This notation recovers the familiar [[group representation|representation]] of the integers as {{math|{..., −2, −1, 0, 1, 2, ...} }}.
+
This notation recovers the familiar representation of the integers as {{math|{..., −2, −1, 0, 1, 2, ...} }}.
  
 
Some examples are:
 
Some examples are:
Line 124: Line 124:
 
\end{align}</math>
 
\end{align}</math>
  
In theoretical computer science, other approaches for the construction of integers are used by [[Automated theorem proving|automated theorem provers]] and [[Rewriting|term rewrite engines]].
+
In theoretical computer science, other approaches for the construction of integers are used by automated theorem provers and term rewrite engines.
Integers are represented as [[Term algebra|algebraic terms]] built using a few basic operations (e.g.,  '''zero''', '''succ''', '''pred''') and, possibly, using [[natural number]]s, which are assumed to be already constructed (using, say, the [[Peano axioms|Peano approach]]).
+
Integers are represented as algebraic terms built using a few basic operations (e.g.,  '''zero''', '''succ''', '''pred''') and, possibly, using natural numbers, which are assumed to be already constructed (using, say, the Peano approach).
  
There exist at least ten such constructions of signed integers.<ref>{{cite conference |last=Garavel |first=Hubert |title=On the Most Suitable Axiomatization of Signed Integers |conference=Post-proceedings of the 23rd International Workshop on Algebraic Development Techniques (WADT'2016) |year=2017 |publisher=Springer |series=Lecture Notes in Computer Science |volume=10644 |pages=120–134 |doi=10.1007/978-3-319-72044-9_9 |url=https://hal.inria.fr/hal-01667321 |access-date=2018-01-25 |archive-url=https://web.archive.org/web/20180126125528/https://hal.inria.fr/hal-01667321 |archive-date=2018-01-26 |url-status=live }}</ref> These constructions differ in several ways: the number of basic operations used for the construction, the number (usually, between 0 and 2) and the types of arguments accepted by these operations; the presence or absence of natural numbers as arguments of some of these operations, and the fact that these operations are free constructors or not, i.e., that the same integer can be represented using only one or many algebraic terms.
+
There exist at least ten such constructions of signed integers. These constructions differ in several ways: the number of basic operations used for the construction, the number (usually, between 0 and 2) and the types of arguments accepted by these operations; the presence or absence of natural numbers as arguments of some of these operations, and the fact that these operations are free constructors or not, i.e., that the same integer can be represented using only one or many algebraic terms.
  
The technique for the construction of integers presented above in this section corresponds to the particular case where there is a single basic operation '''pair'''<math>(x,y)</math> that takes as arguments two natural numbers <math>x</math> and <math>y</math>, and returns an integer (equal to <math>x-y</math>). This operation is not free since the integer 0 can be written '''pair'''(0,0), or '''pair'''(1,1), or '''pair'''(2,2), etc. This technique of construction is used by the [[proof assistant]] [[Isabelle (proof assistant)|Isabelle]]; however, many other tools use alternative construction techniques, notable those based upon free constructors, which are simpler and can be implemented more efficiently in computers.
+
The technique for the construction of integers presented above in this section corresponds to the particular case where there is a single basic operation '''pair'''<math>(x,y)</math> that takes as arguments two natural numbers <math>x</math> and <math>y</math>, and returns an integer (equal to <math>x-y</math>). This operation is not free since the integer 0 can be written '''pair'''(0,0), or '''pair'''(1,1), or '''pair'''(2,2), etc. This technique of construction is used by the proof assistant Isabelle; however, many other tools use alternative construction techniques, notable those based upon free constructors, which are simpler and can be implemented more efficiently in computers.
  
  

Revision as of 14:46, 16 November 2021

An integer is colloquially defined as a number that can be written without a fractional component. For example, 21, 4, 0, and −2048 are integers, while 9.75, Template:Sfrac, and Template:Sqrt are not.

The set of integers consists of zero (Template:Num), the positive natural numbers (Template:Num, Template:Num, Template:Num, ...), also called whole numbers or counting numbers, and their additive inverses (the negative integers, i.e., −1, −2, −3, ...). The set of integers is often denoted by the boldface (Z) or blackboard bold letter "Z".

is a subset of the set of all rational numbers , which in turn is a subset of the real numbers . Like the natural numbers, is countably infinite.

The integers form the smallest group and the smallest ring containing the natural numbers. In algebraic number theory, the integers are sometimes qualified as rational integers to distinguish them from the more general algebraic integers. In fact, (rational) integers are algebraic integers that are also rational numbers.

Symbol

The symbol can be annotated to denote various sets, with varying usage amongst different authors: , or for the positive integers, or for non-negative integers, and for non-zero integers. Some authors use for non-zero integers, while others use it for non-negative integers, or for {–1, 1}Template:Void. Additionally, is used to denote either the set of integers modulo p (i.e., the set of congruence classes of integers), or the set of p-adic integers.

Algebraic properties

Integers can be thought of as discrete, equally spaced points on an infinitely long number line. In the above, non-negative integers are shown in blue and negative integers in red.

Template:Ring theory sidebar

Like the natural numbers, is closed under the operations of addition and multiplication, that is, the sum and product of any two integers is an integer. However, with the inclusion of the negative natural numbers (and importantly, Template:Num), , unlike the natural numbers, is also closed under subtraction.

The integers form a unital ring which is the most basic one, in the following sense: for any unital ring, there is a unique ring homomorphism from the integers into this ring. This universal property, namely to be an initial object in the category of rings, characterizes the ring .

is not closed under division, since the quotient of two integers (e.g., 1 divided by 2) need not be an integer. Although the natural numbers are closed under exponentiation, the integers are not (since the result can be a fraction when the exponent is negative).

The following table lists some of the basic properties of addition and multiplication for any integers a, b and c:

Properties of addition and multiplication on integers
Addition Multiplication
Closure: a + bTemplate:Padis an integer a × bTemplate:Padis an integer
Associativity: a + (b + c) Template:= (a + b) + c a × (b × c) Template:= (a × b) × c
Commutativity: a + b Template:= b + a a × b Template:= b × a
Existence of an identity element: a + 0 Template:= a a × 1 Template:= a
Existence of inverse elements: a + (−a) Template:= 0 The only invertible integers (called units) are −1 and 1.
Distributivity: a × (b + c) Template:= (a × b) + (a × c)Template:PadandTemplate:Pad(a + b) × c Template:= (a × c) + (b × c)
No zero divisors: If a × b Template:= 0, then a Template:= 0 or b Template:= 0 (or both)

The first five properties listed above for addition say that , under addition, is an abelian group. It is also a cyclic group, since every non-zero integer can be written as a finite sum Template:Nowrap or Template:Nowrap. In fact, under addition is the only infinite cyclic group—in the sense that any infinite cyclic group is isomorphic to .

The first four properties listed above for multiplication say that under multiplication is a commutative monoid. However, not every integer has a multiplicative inverse (as is the case of the number 2), which means that under multiplication is not a group.

All the rules from the above property table (except for the last), when taken together, say that together with addition and multiplication is a commutative ring with unity. It is the prototype of all objects of such algebraic structure. Only those equalities of expressions are true in  for all values of variables, which are true in any unital commutative ring. Certain non-zero integers map to zero in certain rings.

The lack of zero divisors in the integers (last property in the table) means that the commutative ring  is an integral domain.

The lack of multiplicative inverses, which is equivalent to the fact that is not closed under division, means that is not a field. The smallest field containing the integers as a subring is the field of rational numbers. The process of constructing the rationals from the integers can be mimicked to form the field of fractions of any integral domain. And back, starting from an algebraic number field (an extension of rational numbers), its ring of integers can be extracted, which includes as its subring.

Although ordinary division is not defined on , the division "with remainder" is defined on them. It is called Euclidean division, and possesses the following important property: given two integers a and b with b ≠ 0, there exist unique integers q and r such that a Template:= q × b + r and 0 ≤ r < |b|, where |b| denotes the absolute value of b. The integer q is called the quotient and r is called the remainder of the division of a by b. The Euclidean algorithm for computing greatest common divisors works by a sequence of Euclidean divisions.

The above says that is a Euclidean domain. This implies that is a principal ideal domain, and any positive integer can be written as the products of primes in an essentially unique way. This is the fundamental theorem of arithmetic.

Order-theoretic properties

is a totally ordered set without upper or lower bound. The ordering of is given by: :... −3 < −2 < −1 < 0 < 1 < 2 < 3 < ... An integer is positive if it is greater than zero, and negative if it is less than zero. Zero is defined as neither negative nor positive.

The ordering of integers is compatible with the algebraic operations in the following way:

  1. if a < b and c < d, then a + c < b + d
  2. if a < b and 0 < c, then ac < bc.

Thus it follows that together with the above ordering is an ordered ring.

The integers are the only nontrivial totally ordered abelian group whose positive elements are well-ordered. This is equivalent to the statement that any Noetherian valuation ring is either a field—or a discrete valuation ring.

Construction

Representation of equivalence classes for the numbers −5 to 5
Red points represent ordered pairs of natural numbers. Linked red points are equivalence classes representing the blue integers at the end of the line.

In elementary school teaching, integers are often intuitively defined as the (positive) natural numbers, zero, and the negations of the natural numbers. However, this style of definition leads to many different cases (each arithmetic operation needs to be defined on each combination of types of integer) and makes it tedious to prove that integers obey the various laws of arithmetic.[1] Therefore, in modern set-theoretic mathematics, a more abstract construction[2] allowing one to define arithmetical operations without any case distinction is often used instead.[3] The integers can thus be formally constructed as the equivalence classes of ordered pairs of natural numbers (a,b).

The intuition is that (a,b) stands for the result of subtracting b from a. To confirm our expectation that Template:Nowrap and Template:Nowrap denote the same number, we define an equivalence relation ~ on these pairs with the following rule:

precisely when

Addition and multiplication of integers can be defined in terms of the equivalent operations on the natural numbers; by using [(a,b)] to denote the equivalence class having (a,b) as a member, one has:

The negation (or additive inverse) of an integer is obtained by reversing the order of the pair:

Hence subtraction can be defined as the addition of the additive inverse:

The standard ordering on the integers is given by:

if and only if

It is easily verified that these definitions are independent of the choice of representatives of the equivalence classes.

Every equivalence class has a unique member that is of the form (n,0) or (0,n) (or both at once). The natural number n is identified with the class [(n,0)] (i.e., the natural numbers are embedded into the integers by map sending n to [(n,0)]), and the class [(0,n)] is denoted n (this covers all remaining classes, and gives the class [(0,0)] a second time since −0 Template:= 0.

Thus, [(a,b)] is denoted by

If the natural numbers are identified with the corresponding integers (using the embedding mentioned above), this convention creates no ambiguity.

This notation recovers the familiar representation of the integers as {..., −2, −1, 0, 1, 2, ...} .

Some examples are:

In theoretical computer science, other approaches for the construction of integers are used by automated theorem provers and term rewrite engines. Integers are represented as algebraic terms built using a few basic operations (e.g., zero, succ, pred) and, possibly, using natural numbers, which are assumed to be already constructed (using, say, the Peano approach).

There exist at least ten such constructions of signed integers. These constructions differ in several ways: the number of basic operations used for the construction, the number (usually, between 0 and 2) and the types of arguments accepted by these operations; the presence or absence of natural numbers as arguments of some of these operations, and the fact that these operations are free constructors or not, i.e., that the same integer can be represented using only one or many algebraic terms.

The technique for the construction of integers presented above in this section corresponds to the particular case where there is a single basic operation pair that takes as arguments two natural numbers and , and returns an integer (equal to ). This operation is not free since the integer 0 can be written pair(0,0), or pair(1,1), or pair(2,2), etc. This technique of construction is used by the proof assistant Isabelle; however, many other tools use alternative construction techniques, notable those based upon free constructors, which are simpler and can be implemented more efficiently in computers.


Licensing

Content obtained and/or adapted from:

  • Template:Cite book.
  • Ivorra Castillo: Álgebra
  • Template:Cite book.