Integer
An integer is the
The set of natural numbers is a subset of which in turn is a subset of the set of all rational numbers itself a subset of the real numbers [a] Like the set of natural numbers, the set of integers is countably infinite. An integer may be regarded as a real number that can be written without a fractional component. For example, 21, 4, 0, and −2048 are integers, while 9.75, 5+1/2, 5/4 and √2 are not.[8]
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.
History
The word integer comes from the
The phrase the set of the integers was not used before the end of the 19th century, when Georg Cantor introduced the concept of infinite sets and set theory. The use of the letter Z to denote the set of integers comes from the German word Zahlen ("numbers")[3][4] and has been attributed to David Hilbert.[16] The earliest known use of the notation in a textbook occurs in Algèbre written by the collective Nicolas Bourbaki, dating to 1947.[3][17] The notation was not adopted immediately, for example another textbook used the letter J[18] and a 1960 paper used Z to denote the non-negative integers.[19] But by 1961, Z was generally used by modern algebra texts to denote the positive and negative integers.[20]
The symbol is often 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} (the
The whole numbers were synonymous with the integers up until the early 1950s.[23][24][25] In the late 1950s, as part of the New Math movement,[26] American elementary school teachers began teaching that whole numbers referred to the natural numbers, excluding negative numbers, while integer included the negative numbers.[27][28] The whole numbers remain ambiguous to the present day.[29]
Algebraic properties
Algebraic structure → Group theory Group theory |
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Algebraic structure → Ring theory Ring theory |
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Like the
The integers form a
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:
Addition | Multiplication | |
---|---|---|
Closure: | a + b is an integer | a × b is an integer |
Associativity :
|
a + (b + c) = (a + b) + c | a × (b × c) = (a × b) × c |
Commutativity :
|
a + b = b + a | a × b = b × a |
Existence of an identity element: | a + 0 = a | a × 1 = a |
Existence of inverse elements: | a + (−a) = 0 | The only invertible integers (called units) are −1 and 1. |
Distributivity :
|
a × (b + c) = (a × b) + (a × c) and (a + b) × c = (a × c) + (b × c) | |
No zero divisors: | If a × b = 0, then a = 0 or b = 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 1 + 1 + ... + 1 or (−1) + (−1) + ... + (−1). 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
All the rules from the above property table (except for the last), when taken together, say that together with addition and multiplication is a
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 = 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.[31] 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:
- if a < b and c < d, then a + c < b + d
- 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
Construction
Traditional development
In elementary school teaching, integers are often intuitively defined as the union of the (positive) natural numbers,
The traditional arithmetic operations can then be defined on the integers in a
The traditional 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.[34]
Equivalence classes of ordered pairs
In modern set-theoretic mathematics, a more abstract construction[35][36] allowing one to define arithmetical operations without any case distinction is often used instead.[37] The integers can thus be formally constructed as the equivalence classes of ordered pairs of natural numbers (a,b).[38]
The intuition is that (a,b) stands for the result of subtracting b from a.[38] To confirm our expectation that 1 − 2 and 4 − 5 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;[38] 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:
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 = 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:
Other approaches
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.[39] 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 in the previous 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.
Computer science
An integer is often a primitive
, etc.).Variable-length representations of integers, such as
Cardinality
The set of integers is
- (0, 1), (1, 2), (−1, 3), (2, 4), (−2, 5), (3, 6), . . . ,(1 − k, 2k − 1), (k, 2k ), . . .
More technically, the cardinality of is said to equal ℵ0 (aleph-null). The pairing between elements of and is called a bijection.
See also
- Canonical factorization of a positive integer
- Complex integer
- Hyperinteger
- Integer complexity
- Integer lattice
- Integer part
- Integer sequence
- Integer-valued function
- Mathematical symbols
- Parity (mathematics)
- Profinite integer
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Footnotes
- ^ More precisely, each system is embedded in the next, isomorphically mapped to a subset.[5] The commonly-assumed set-theoretic containment may be obtained by constructing the reals, discarding any earlier constructions, and defining the other sets as subsets of the reals.[6] Such a convention is "a matter of choice", yet not.[7]
References
- ISBN 978-0-226-74267-0.
- ^ Hillman, Abraham P.; Alexanderson, Gerald L. (1963). Algebra and trigonometry;. Boston: Allyn and Bacon.
- ^ a b c Miller, Jeff (29 August 2010). "Earliest Uses of Symbols of Number Theory". Archived from the original on 31 January 2010. Retrieved 20 September 2010.
- ^ ISBN 978-0-19-850195-4. Archivedfrom the original on 8 December 2016. Retrieved 15 February 2016.
- ISBN 978-90-277-2245-4.
The natural numbers are not themselves a subset of this set-theoretic representation of the integers. Rather, the set of all integers contains a subset consisting of the positive integers and zero which is isomorphic to the set of natural numbers.
- ISBN 978-0-486-14168-8.
- ISBN 978-0-19-162189-5.
- ISBN 978-1-5062-4844-8.
- ISBN 978-0-7923-3352-4.
- ^ Smedley, Edward; Rose, Hugh James; Rose, Henry John (1845). Encyclopædia Metropolitana. B. Fellowes. p. 537.
An integer is a multiple of unity
- ^ Encyclopaedia Britannica 1771, p. 367
- ^ Pisano, Leonardo; Boncompagni, Baldassarre (transliteration) (1202). Incipit liber Abbaci compositus to Lionardo filio Bonaccii Pisano in year Mccij [The Book of Calculation] (Manuscript) (in Latin). Translated by Sigler, Laurence E. Museo Galileo. p. 30.
Nam rupti uel fracti semper ponendi sunt post integra, quamuis prius integra quam rupti pronuntiari debeant.
[And the fractions are always put after the whole, thus first the integer is written, and then the fraction] - ^ Encyclopaedia Britannica 1771, p. 83
- ^ Martinez, Alberto (2014). Negative Math. Princeton University Press. pp. 80–109.
- ^ Euler, Leonhard (1771). Vollstandige Anleitung Zur Algebra [Complete Introduction to Algebra] (in German). Vol. 1. p. 10.
Alle diese Zahlen, so wohl positive als negative, führen den bekannten Nahmen der gantzen Zahlen, welche also entweder größer oder kleiner sind als nichts. Man nennt dieselbe gantze Zahlen, um sie von den gebrochenen, und noch vielerley andern Zahlen, wovon unten gehandelt werden wird, zu unterscheiden.
[All these numbers, both positive and negative, are called whole numbers, which are either greater or lesser than nothing. We call them whole numbers, to distinguish them from fractions, and from several other kinds of numbers of which we shall hereafter speak.] - ^ The University of Leeds Review. Vol. 31–32. University of Leeds. 1989. p. 46.
Incidentally, Z comes from "Zahl": the notation was created by Hilbert.
- ^ Bourbaki, Nicolas (1951). Algèbre, Chapter 1 (in French) (2nd ed.). Paris: Hermann. p. 27.
Le symétrisé de N se note Z; ses éléments sont appelés entiers rationnels.
[The group of differences of N is denoted by Z; its elements are called the rational integers.] - ^ Birkhoff, Garrett (1948). Lattice Theory (Revised ed.). American Mathematical Society. p. 63.
the set J of all integers
- ^ Society, Canadian Mathematical (1960). Canadian Journal of Mathematics. Canadian Mathematical Society. p. 374.
Consider the set Z of non-negative integers
- ^ Bezuszka, Stanley (1961). Contemporary Progress in Mathematics: Teacher Supplement [to] Part 1 and Part 2. Boston College. p. 69.
Modern Algebra texts generally designate the set of integers by the capital letter Z.
- ^ Keith Pledger and Dave Wilkins, "Edexcel AS and A Level Modular Mathematics: Core Mathematics 1" Pearson 2008
- ^ LK Turner, FJ BUdden, D Knighton, "Advanced Mathematics", Book 2, Longman 1975.
- ^ Mathews, George Ballard (1892). Theory of Numbers. Deighton, Bell and Company. p. 2.
- ^ Betz, William (1934). Junior Mathematics for Today. Ginn.
The whole numbers, or integers, when arranged in their natural order, such as 1, 2, 3, are called consecutive integers.
- ^ Peck, Lyman C. (1950). Elements of Algebra. McGraw-Hill. p. 3.
The numbers which so arise are called positive whole numbers, or positive integers.
- .
A much more influential force in bringing news of the "new math" to high school teachers and administrators was the National Council of Teachers of Mathematics (NCTM).
- ISBN 9780608166186.
- ^ Deans, Edwina (1963). Elementary School Mathematics: New Directions. U.S. Department of Health, Education, and Welfare, Office of Education. p. 42.
- ^ "entry: whole number". The American Heritage Dictionary. HarperCollins.
- ^ "Integer | mathematics". Encyclopedia Britannica. Retrieved 11 August 2020.
- ISBN 978-0-201-55540-0.
- ISBN 978-0-486-13709-4. Archivedfrom the original on 6 September 2015. Retrieved 29 April 2015..
- ISBN 978-0-89874-818-5.
- ISBN 978-0-486-45792-5. Archivedfrom the original on 8 December 2016. Retrieved 15 February 2016..
- ^ Ivorra Castillo: Álgebra
- ISBN 978-3-319-69427-6.
- ISBN 978-0-7487-3515-0. Archivedfrom the original on 8 December 2016. Retrieved 15 February 2016..
- ^ ISBN 978-0-390-16895-5.
- ISBN 978-3-319-72043-2. Archivedfrom the original on 26 January 2018. Retrieved 25 January 2018.
Sources
- ISBN 0-671-46400-0.)
- Herstein, I.N. (1975). Topics in Algebra (2nd ed.). Wiley. ISBN 0-471-01090-1.
- ISBN 0-8218-1646-2.
- A Society of Gentlemen in Scotland (1771). Encyclopaedia Britannica. Edinburgh.
External links
- "Integer", Encyclopedia of Mathematics, EMS Press, 2001 [1994]
- The Positive Integers – divisor tables and numeral representation tools
- On-Line Encyclopedia of Integer Sequences cf OEIS
- Weisstein, Eric W. "Integer". MathWorld.
This article incorporates material from Integer on