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In mathematics, a Gaussian rational number is a complex number of the form p + qi, where p and q are both rational numbers. The set of all Gaussian rationals forms the Gaussian rational field, denoted Q(i), obtained by adjoining the imaginary number i to the field of rationals Q.

Properties of the field

The field of Gaussian rationals provides an example of an algebraic number field that is both a quadratic field and a cyclotomic field (since i is a 4th root of unity). Like all quadratic fields it is a Galois extension of Q with Galois group cyclic of order two, in this case generated by complex conjugation, and is thus an abelian extension of Q, with conductor 4.^[1]

As with cyclotomic fields more generally, the field of Gaussian rationals is neither ordered nor complete (as a metric space). The Gaussian integers Z[i] form the ring of integers of Q(i). The set of all Gaussian rationals is countably infinite.

The field of Gaussian rationals is also a two-dimensional vector space over Q with natural basis $\{1,i\}$ .

Ford spheres

The concept of Ford circles can be generalized from the rational numbers to the Gaussian rationals, giving Ford spheres. In this construction, the complex numbers are embedded as a plane in a three-dimensional Euclidean space, and for each Gaussian rational point in this plane one constructs a sphere tangent to the plane at that point. For a Gaussian rational represented in lowest terms as $p/q$ (i.e. ⁠ $p$ ⁠ and ⁠ $q$ ⁠ are relatively prime), the radius of this sphere should be $1/2|q|^{2}$ where $|q|^{2}=q{\bar {q}}$ is the squared modulus, and ⁠ ${\bar {q}}$ ⁠ is the complex conjugate. The resulting spheres are tangent for pairs of Gaussian rationals $P/Q$ and $p/q$ with $|Pq-pQ|=1$ , and otherwise they do not intersect each other.^[2]^[3]

References

^ Ian Stewart, David O. Tall, Algebraic Number Theory, Chapman and Hall, 1979, ISBN 0-412-13840-9. Chap.3.
^ Pickover, Clifford A. (2001), "Chapter 103. Beauty and Gaussian Rational Numbers", Wonders of Numbers: Adventures in Mathematics, Mind, and Meaning, Oxford University Press, pp. 243–246, ISBN 9780195348002.
^ Northshield, Sam (2015), Ford Circles and Spheres, arXiv:1503.00813, Bibcode:2015arXiv150300813N.

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[1] Ian Stewart, David O. Tall, Algebraic Number Theory, Chapman and Hall, 1979, ISBN 0-412-13840-9. Chap.3.

[2] Pickover, Clifford A. (2001), "Chapter 103. Beauty and Gaussian Rational Numbers", Wonders of Numbers: Adventures in Mathematics, Mind, and Meaning, Oxford University Press, pp. 243–246, ISBN 9780195348002.

[3] Northshield, Sam (2015), Ford Circles and Spheres, arXiv:1503.00813, Bibcode:2015arXiv150300813N.

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+{{Short description|Complex number with rational components}}
 In [[mathematics]], a '''Gaussian rational''' number is a [[complex number]] of the form ''p''&nbsp;+&nbsp;''qi'', where ''p'' and ''q'' are both [[rational number]]s.
-The set of all Gaussian rationals forms the Gaussian rational [[field (mathematics)|field]], denoted '''Q'''(''i''), obtained by adjoining the [[imaginary number]] ''i'' to the field of rationals.
+The set of all Gaussian rationals forms the Gaussian rational [[field (mathematics)|field]], denoted '''Q'''(''i''), obtained by adjoining the [[imaginary number]] ''i'' to the field of rationals '''Q'''.
-It thus provides an example of an [[algebraic number field]], which is both a [[quadratic field]] and a [[cyclotomic field]] (since  ''i'' is a 4th [[root of unity]]).  Like all quadratic fields it is a [[Galois extension]] of '''Q''' with [[Galois group]] [[cyclic group|cyclic]] of order two, in this case generated by [[complex conjugation]], and is thus an [[abelian extension]] of '''Q''', with [[conductor (algebraic number theory)|conductor]] 4.
+==Properties of the field==
-The field of Gaussian rationals is neither [[ordered field|ordered]] nor topologically [[complete space|complete]]. The [[Gaussian integer]]s '''Z'''[''i''] form the [[ring of integers]] of '''Q'''(''i'').
+The field of Gaussian rationals provides an example of an [[algebraic number field]] that is both a [[quadratic field]] and a [[cyclotomic field]] (since  ''i'' is a 4th [[root of unity]]).  Like all quadratic fields it is a [[Galois extension]] of '''Q''' with [[Galois group]] [[cyclic group|cyclic]] of order two, in this case generated by [[complex conjugation]], and is thus an [[abelian extension]] of '''Q''', with [[conductor (algebraic number theory)|conductor]] 4.<ref>[[Ian Stewart (mathematician)|Ian Stewart]], [[David O. Tall]], ''Algebraic Number Theory'', [[Chapman and Hall]], 1979, {{ISBN|0-412-13840-9}}. Chap.3.</ref>
+As with cyclotomic fields more generally, the field of Gaussian rationals is neither [[ordered field|ordered]] nor [[complete space|complete]] (as a metric space). The [[Gaussian integer]]s '''Z'''[''i''] form the [[ring of integers]] of '''Q'''(''i''). The set of all Gaussian rationals is [[countable set|countably infinite]].
+The field of Gaussian rationals is also a two-dimensional [[vector space]] over '''Q''' with natural [[Basis (linear algebra)|basis]] <math>\{1, i\}</math>.
+==Ford spheres==
+The concept of [[Ford circle]]s can be generalized from the rational numbers to the Gaussian rationals, giving Ford spheres. In this construction, the complex numbers are embedded as a plane in a three-dimensional [[Euclidean space]], and for each Gaussian rational point in this plane one constructs a sphere tangent to the plane at that point. For a Gaussian rational represented in lowest terms as <math>p/q</math> (i.e. {{tmath|p}} and {{tmath|q}} are relatively prime), the radius of this sphere should be <math>1/2|q|^2</math> where <math>|q|^2 = q \bar q</math> is the squared modulus, and {{tmath|\bar q}} is the [[complex conjugate]]. The resulting spheres are [[tangent]] for pairs of Gaussian rationals <math>P/Q</math> and <math>p/q</math> with <math>|Pq-pQ|=1</math>, and otherwise they do not intersect each other.<ref>{{citation|title=Wonders of Numbers: Adventures in Mathematics, Mind, and Meaning|first=Clifford A.|last=Pickover|authorlink=Clifford A. Pickover|publisher=Oxford University Press|year=2001|isbn=9780195348002|contribution=Chapter 103. Beauty and Gaussian Rational Numbers|pages=243–246|url=https://books.google.com/books?id=52N0JJBspM0C&pg=PA243}}.</ref><ref>{{citation|year=2015|arxiv=1503.00813|title=Ford Circles and Spheres|first=Sam|last=Northshield|bibcode=2015arXiv150300813N}}.</ref>
 ==References==
+{{reflist}}
-* [[Ian Stewart (mathematician)|Ian Stewart]], [[David O. Tall]], ''Algebraic Number Theory'', [[Chapman and Hall]], 1979, ISBN 0-412-13840-9. Chap.3.
 [[Category:Cyclotomic fields]]
 {{Numtheory-stub}}
+{{Number systems}}
-[[fr:Rationnel de Gauss]]
 [[it:Intero di Gauss#Campo dei quozienti]]

v t e Number systems
Sets of definable numbers	Natural numbers ( $\mathbb {N}$ ) Integers ( $\mathbb {Z}$ ) Rational numbers ( $\mathbb {Q}$ ) Constructible numbers Algebraic numbers ( $\mathbb {A}$ ) Closed-form numbers Periods ( ${\mathcal {P}}$ ) Computable numbers Arithmetical numbers Set-theoretically definable numbers Gaussian integers Gaussian rationals Eisenstein integers
Composition algebras	Division algebras: Real numbers ( $\mathbb {R}$ ) Complex numbers ( $\mathbb {C}$ ) Quaternions ( $\mathbb {H}$ ) Octonions ( $\mathbb {O}$ )
Split types	Over $\mathbb {R}$ : Split-complex numbers Split-quaternions Split-octonions Over $\mathbb {C}$ : Bicomplex numbers Biquaternions Bioctonions
Other hypercomplex	Dual numbers Dual quaternions Dual-complex numbers Hyperbolic quaternions Sedenions ( $\mathbb {S}$ ) Trigintaduonions ( $\mathbb {T}$ ) Split-biquaternions Multicomplex numbers Geometric algebra/Clifford algebra Algebra of physical space Spacetime algebra Plane-based geometric algebra
Infinities and infinitesimals	Cardinal numbers Extended natural numbers Extended real numbers Projective Extended complex numbers Hyperreal numbers Levi-Civita field Ordinal numbers Supernatural numbers Surreal numbers Superreal numbers
Other types	Irrational numbers Fuzzy numbers Transcendental numbers p-adic numbers (p-adic solenoids) Profinite integers Normal numbers
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