Rational number: Difference between revisions

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A rational number is a number that can be expressed as the ratio of two integers.

Examples

All integers are rational because every integer $a$ can be represented as $\frac{a}{1}$
Every number with a finite decimal expansion is rational (for example, $12.345=\frac{12345}{1000}$ )
Every number with a periodic decimal expansion (for example, 0.314314314...) is also rational.

Moreover, any rational number in any base satisfies exactly one of the last two conditions.

Properties

Rational numbers form a field. In plain English it means that you can add, subtract, multiply, and divide them (with the exception of division by $0$ ) and the result of each such operation is again a rational number.
Rational numbers are dense in the set of reals. This means that every non- empty open interval on the real line contains at least one (actually, infinitely many) rationals. Alternatively, it means that every real number can be represented as a limit of a sequence of rational numbers.
Despite this, the set of rational numbers is countable, i.e. the same size as the set of integers.

@@ Line 1: / Line 1: @@
-==Definition==
+A '''rational number''' is a [[number]] that can be expressed as the [[ratio]] of two [[integer]]s.
-A number is called rational if it can be represented as a ratio of two [[integer]]s.
-==Examples==
+== Examples ==
-* All integers are rational because every integer <math>a</math> can be represented as <math>a=\frac a1</math> (or <math>\frac{2a}2</math>, or...)
-* All numbers whose [[decimal expansion]] or expansion in some other number [[base]] is finite are rational (say, <math>12.345=\frac{12345}{1000}</math>)
+* All integers are rational because every integer <math>a</math> can be represented as <math>\frac{a}{1}</math>
-* All numbers whose decimal expansion is [[periodic]] are rationals.
+* Every number with a finite [[decimal expansion]] is rational (for example, <math>12.345=\frac{12345}{1000}</math>)
-Actually, the last property characterizes rationals among all [[real number]]s.
+* Every number with a periodic decimal expansion (for example, 0.314314314...) is also rational.
+Moreover, any rational number in any [[base numbers|base]] satisfies exactly one of the last two conditions.
 ==Properties==
-# Rational numbers form a [[commutative]] [[field]]. In plain English it means that you can add, subtract, multiply, and divide them (with the obvious exception of division by <math>0</math>) and the result of each such operation is again a rational number.
-# Rational numbers are [[dense]] in the set of reals. This means that every non-empty open interval on the real line contains at least one (actually, infinitely many) rationals. Alternatively, it means that every real number can be represented as a [[limit]] of a [[sequence]] of rational numbers.
+* Rational numbers form a [[field]]. In plain English it means that you can add, subtract, multiply, and divide them (with the exception of division by <math>0</math>) and the result of each such operation is again a rational number.
-==See also==
+* Rational numbers are [[dense]] in the set of reals. This means that every non-[[empty set | empty]] [[open interval]] on the real line contains at least one (actually, infinitely many) rationals. Alternatively, it means that every real number can be represented as a [[limit]] of a [[sequence]] of rational numbers.
-[[rational approximation]]
+* Despite this, the set of rational numbers is [[countable]], i.e. the same size as the set of integers.
+== See also ==
+* [[Fraction]]
+* [[Rational approximation]]
+[[Category:Definition]]
+[[Category:Number theory]]
+{{stub}}

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Rational number: Difference between revisions

Latest revision as of 21:00, 3 February 2025

Examples

Properties

See also