Algebraic function field: Difference between revisions

Latest revision as of 23:58, 25 June 2025

Template:Short description Template:Refimprove In mathematics, an algebraic function field (often abbreviated as function field) of $n$ variables over a field $k$ is a finitely generated field extension $K / k$ which has transcendence degree $n$ over $k$ .^[1] Equivalently, an algebraic function field of $n$ variables over $k$ may be defined as a finite field extension of the field $K = k (x_{1}, \dots, x_{n})$ of rational functions in $n$ variables over $k$ .

Example

As an example, in the polynomial ring $k [x, y]$ consider the ideal generated by the irreducible polynomial $y^{2} - x^{3}$ and form the field of fractions of the quotient ring $k [x, y] / (y^{2} - x^{3})$ . This is a function field of one variable over $k$ ; it can also be written as $k (x) (\sqrt{x^{3}})$ (with degree 2 over $k (x)$ ) or as $k (y) (\sqrt[3]{y^{2}})$ (with degree 3 over $k (y)$ ). We see that the degree of an algebraic function field is not a well-defined notion.

Category structure

The algebraic function fields over $k$ form a category; the morphisms from function field $K$ to $L$ are the ring homomorphisms $f : K \to L$ with $f (a) = a$ for all $a$ in $k$ . All these morphisms are injective. If $K$ is a function field over $k$ of $n$ variables, and $L$ is a function field in $m$ variables, and $n > m$ , then there are no morphisms from $K$ to $L$ .

Function fields arising from varieties, curves and Riemann surfaces

The function field of an algebraic variety of dimension $n$ over $k$ is an algebraic function field of $n$ variables over $k$ . Two varieties are birationally equivalent if and only if their function fields are isomorphic (but note that non-isomorphic varieties may have the same function field). Assigning to each variety its function field yields a duality (contravariant equivalence) between the category of varieties over $k$ (with dominant rational maps as morphisms) and the category of algebraic function fields over $k$ . The varieties considered here are to be taken in the scheme sense; they need not have any $k$ -rational points, like the curve $x^{2} + y^{2} + 1 = 0$ defined over the real numbers.

The case $n = 1$ (irreducible algebraic curves in the scheme sense) is especially important, since every function field of one variable over $k$ arises as the function field of a uniquely defined regular (i.e. non-singular) projective irreducible algebraic curve over $k$ . In fact, the function field yields a duality between the category of regular projective irreducible algebraic curves (with dominant regular maps as morphisms) and the category of function fields of one variable over $k$ .

The field $M (X)$ of meromorphic functions defined on a connected Riemann surface $X$ is a function field of one variable over the complex numbers $ℂ$ . In fact, $M (X)$ yields a duality between the category of compact connected Riemann surfaces (with non-constant holomorphic maps as morphisms) and function fields of one variable over $ℂ$ . A similar correspondence exists between compact connected Klein surfaces and function fields in one variable over $ℝ$ .

Number fields and finite fields

The function field analogy states that almost all theorems on number fields have a counterpart on function fields of one variable over a finite field, and these counterparts are frequently easier to prove (see analogue for irreducible polynomials over a finite field). In the context of this analogy, both number fields and function fields over finite fields are usually called "global fields".

The study of function fields over a finite field has applications in cryptography and error correcting codes. For example, the function field of an elliptic curve over a finite field (an important mathematical tool for public key cryptography) is an algebraic function field.

Function fields over the field of rational numbers play also an important role in solving inverse Galois problems.

Field of constants

Given any algebraic function field $K$ over $k$ , we can consider the set of elements of $K$ which are algebraic over $k$ . These elements form a field, known as the field of constants of the algebraic function field.

For instance, $ℂ (x)$ is a function field of one variable over $ℝ$ ; its field of constants is $ℂ$ .

Valuations and places

Key tools to study algebraic function fields are absolute values, valuations, places and their completions.

Given an algebraic function field $K / k$ of one variable, we define the notion of a valuation ring of $K / k$ : this is a subring $𝒪$ of $K$ that contains $k$ and is different from $k$ and $K$ , and such that for any $x$ in $K$ we have $x \in 𝒪$ or $x^{- 1} \in 𝒪$ . Each such valuation ring is a discrete valuation ring and its maximal ideal is called a place of $K / k$ .

A discrete valuation of $K / k$ is a surjective function $v : K \to ℤ \cup {\infty}$ such that for all $x, y \in K$ ,

$v (x y) = v (x) + v (y)$ ,
$v (x + y) \geq \min {v (x), v (y)}$ ,
$v (x) = \infty ⟺ x = 0$

and $v (a) = 0$ for all $a \in k ∖ {0}$ .

There are natural bijective correspondences between the set of valuation rings of $K / k$ , the set of places of $K / k$ , and the set of discrete valuations of $K / k$ . These sets can be given a natural topological structure: the Zariski–Riemann space of $K / k$ .

References

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@@ Line 1: / Line 1: @@
 {{short description|Finitely generated extension field of positive transcendence degree}}
 {{refimprove|date=December 2021}}
-In [[mathematics]], an '''algebraic function field''' (often abbreviated as '''function field''') of ''n'' variables over a [[field (mathematics)|field]] ''k'' is a finitely generated [[field extension]] ''K''/''k'' which has [[transcendence degree]] ''n'' over ''k''.<ref>{{cite book |author=Gabriel Daniel |author2=Villa Salvador |name-list-style=amp|title=Topics in the Theory of Algebraic Function Fields|publisher=Springer |year= 2007|isbn=9780817645151|url=https://books.google.com/books?id=RmKpEUltmQIC}}</ref> Equivalently, an algebraic function field of ''n'' variables over ''k'' may be defined as a [[finite field extension]] of the field ''K'' = ''k''(''x''<sub>1</sub>,...,''x''<sub>''n''</sub>) of [[rational functions]] in ''n'' variables over ''k''.
+In [[mathematics]], an '''algebraic function field''' (often abbreviated as '''function field''') of <math>n</math> variables over a [[field (mathematics)|field]] <math>k</math> is a finitely generated [[field extension]] <math>K/k</math> which has [[transcendence degree]] <math>n</math> over <math>k</math>.<ref>{{cite book |author=Gabriel Daniel |author2=Villa Salvador |name-list-style=amp|title=Topics in the Theory of Algebraic Function Fields|publisher=Springer |year= 2007|isbn=9780817645151|url=https://books.google.com/books?id=RmKpEUltmQIC}}</ref> Equivalently, an algebraic function field of <math>n</math> variables over <math>k</math> may be defined as a [[finite field extension]] of the field <math>K=k(x_1,\dots,x_n)</math> of [[rational functions]] in <math>n</math> variables over <math>k</math>.
 ==Example==
-As an example, in the [[polynomial ring]] ''k''{{space|hair}}[''X'',''Y''] consider the [[ideal (ring theory)|ideal]] generated by the [[irreducible polynomial]] ''Y''<sup>{{space|hair}}2</sup>&thinsp;−&thinsp;''X''<sup>{{space|hair}}3</sup> and form the [[field of fractions]] of the [[quotient ring]] ''k''{{space|hair}}[''X'',''Y'']/(''Y''<sup>{{space|hair}}2</sup>&thinsp;−&thinsp;''X''<sup>{{space|hair}}3</sup>). This is a function field of one variable over ''k''; it can also be written as <math>k(X)(\sqrt{X^3})</math> (with degree 2 over <math>k(X)</math>) or as <math>k(Y)(\sqrt[3]{Y^2})</math> (with degree 3 over <math>k(Y)</math>). We see that the degree of an algebraic function field is not a well-defined notion.
+As an example, in the [[polynomial ring]] <math>k[x,y]</math> consider the [[ideal (ring theory)|ideal]] generated by the [[irreducible polynomial]] <math>y^2-x^3</math> and form the [[field of fractions]] of the [[quotient ring]] <math>k[x,y]/(y^2-x^3)</math>. This is a function field of one variable over <math>k</math>; it can also be written as <math>k(x)(\sqrt{x^3})</math> (with degree 2 over <math>k(x)</math>) or as <math>k(y)(\sqrt[3]{y^2})</math> (with degree 3 over <math>k(y)</math>). We see that the degree of an algebraic function field is not a well-defined notion.
 ==Category structure==
-The algebraic function fields over ''k'' form a [[category (mathematics)|category]]; the [[Morphism (category theory)|morphisms]] from function field ''K'' to ''L'' are the [[ring homomorphism]]s ''f''&nbsp;:&nbsp;''K'' → ''L'' with ''f''(''a'') = ''a'' for all ''a'' in ''k''. All these morphisms are [[injective function|injective]]. If ''K'' is a function field over ''k'' of ''n'' variables, and ''L'' is a function field in ''m'' variables, and ''n'' > ''m'', then there are no morphisms from ''K'' to ''L''.
+The algebraic function fields over <math>k</math> form a [[category (mathematics)|category]]; the [[Morphism (category theory)|morphisms]] from function field <math>K</math> to <math>L</math> are the [[ring homomorphism]]s <math>f:K\to L</math> with <math>f(a)=a</math> for all <math>a</math> in <math>k</math>. All these morphisms are [[injective function|injective]]. If <math>K</math> is a function field over <math>k</math> of <math>n</math> variables, and <math>L</math> is a function field in <math>m</math> variables, and <math>n>m</math>, then there are no morphisms from <math>K</math> to <math>L</math>.
 ==Function fields arising from varieties, curves and Riemann surfaces==
-The [[function field of an algebraic variety]] of dimension ''n'' over ''k'' is an algebraic function field of ''n'' variables over ''k''.
+The [[function field of an algebraic variety]] of dimension <math>n</math> over <math>k</math> is an algebraic function field of <math>n</math> variables over <math>k</math>.
-Two varieties are [[birational geometry|birationally equivalent]] if and only if their function fields are isomorphic. (But note that non-[[morphism of varieties|isomorphic]] varieties may have the same function field!) Assigning to each variety its function field yields a [[equivalence of categories|duality]] (contravariant equivalence) between the category of varieties over ''k'' (with [[rational mapping|dominant rational maps]] as morphisms) and the category of algebraic function fields over ''k''. (The varieties considered here are to be taken in the [[scheme (mathematics)|scheme]] sense; they need not have any ''k''-rational points, like the curve {{math|1=''X''<sup>2</sup> + ''Y''<sup>2</sup> + 1 = 0}} defined over the [[Real number|reals]], that is with {{math|1=''k'' = '''R'''}}.)
+Two varieties are [[birational geometry|birationally equivalent]] if and only if their function fields are isomorphic (but note that non-[[morphism of varieties|isomorphic]] varieties may have the same function field). Assigning to each variety its function field yields a [[equivalence of categories|duality]] (contravariant equivalence) between the category of varieties over <math>k</math> (with [[rational mapping|dominant rational maps]] as morphisms) and the category of algebraic function fields over <math>k</math>. The varieties considered here are to be taken in the [[scheme (mathematics)|scheme]] sense; they need not have any <math>k</math>-rational points, like the curve <math>x^2+y^2+1=0</math> defined over the real numbers.
-The case ''n''&thinsp;=&thinsp;1 (irreducible algebraic curves in the [[scheme (mathematics)|scheme]] sense) is especially important, since every function field of one variable over ''k'' arises as the function field of a uniquely defined [[regular scheme|regular]] (i.e. non-singular) projective irreducible algebraic curve over ''k''. In fact, the function field yields a duality between the category of regular projective irreducible algebraic curves (with [[Glossary of scheme theory#dominant|dominant]] [[regular map (algebraic geometry)|regular map]]s as morphisms) and the category of function fields of one variable over ''k''.
+The case <math>n=1</math> (irreducible algebraic curves in the [[scheme (mathematics)|scheme]] sense) is especially important, since every function field of one variable over <math>k</math> arises as the function field of a uniquely defined [[regular scheme|regular]] (i.e. non-singular) projective irreducible algebraic curve over <math>k</math>. In fact, the function field yields a duality between the category of regular projective irreducible algebraic curves (with [[Glossary of scheme theory#dominant|dominant]] [[regular map (algebraic geometry)|regular map]]s as morphisms) and the category of function fields of one variable over <math>k</math>.
-The field M(''X'') of [[meromorphic function]]s defined on a connected [[Riemann surface]] ''X'' is a function field of one variable over the [[complex number]]s '''C'''. In fact, M yields a duality (contravariant equivalence) between the category of compact connected Riemann surfaces (with non-constant [[holomorphic]] maps as morphisms) and function fields of one variable over '''C'''. A similar correspondence exists between compact connected [[Klein surface]]s and function fields in one variable over '''R'''.
+The field <math>M(X)</math> of [[meromorphic function]]s defined on a connected [[Riemann surface]] <math>X</math> is a function field of one variable over the [[complex number]]s <math>\C</math>. In fact, <math>M(X)</math> yields a duality between the category of compact connected Riemann surfaces (with non-constant [[holomorphic]] maps as morphisms) and function fields of one variable over <math>\C</math>. A similar correspondence exists between compact connected [[Klein surface]]s and function fields in one variable over <math>\R</math>.
 ==Number fields and finite fields==
-The [[function field analogy]] states that almost all theorems on [[number field]]s have a counterpart on function fields of one variable over a [[finite field]], and these counterparts are frequently easier to prove. (For example, see [[Prime number theorem#Analogue for irreducible polynomials over a finite field|Analogue for irreducible polynomials over a finite field]].) In the context of this analogy, both number fields and function fields over finite fields are usually called "[[global field]]s".
+The [[function field analogy]] states that almost all theorems on [[number field]]s have a counterpart on function fields of one variable over a [[finite field]], and these counterparts are frequently easier to prove (see [[Prime number theorem#Analogue for irreducible polynomials over a finite field|analogue for irreducible polynomials over a finite field]]). In the context of this analogy, both number fields and function fields over finite fields are usually called "[[global field]]s".
 The study of function fields over a finite field has applications in [[cryptography]] and [[error correcting code]]s. For example, the function field of an [[elliptic curve]] over a finite field (an important mathematical tool for [[public key cryptography]]) is an algebraic function field.
@@ Line 25: / Line 25: @@
 ==Field of constants==
-Given any algebraic function field ''K'' over ''k'', we can consider the [[Set (mathematics)|set]] of elements of ''K'' which are [[algebraic element|algebraic]] over ''k''. These elements form a field, known as the ''field of constants'' of the algebraic function field.
+Given any algebraic function field <math>K</math> over <math>k</math>, we can consider the [[Set (mathematics)|set]] of elements of <math>K</math> which are [[algebraic element|algebraic]] over <math>k</math>. These elements form a field, known as the ''field of constants'' of the algebraic function field.
-For instance, '''C'''(''x'') is a function field of one variable over '''R'''; its field of constants is '''C'''.
+For instance, <math>\C(x)</math> is a function field of one variable over <math>\R</math>; its field of constants is <math>\C</math>.
 ==Valuations and places==
 Key tools to study algebraic function fields are [[absolute value (algebra)|absolute values, valuations, places]] and their completions.
-Given an algebraic function field ''K''/''k'' of one variable, we define the notion of a ''valuation ring'' of ''K''/''k'': this is a [[subring]] ''O'' of ''K'' that contains ''k'' and is different from ''k'' and ''K'', and such that for any ''x'' in ''K'' we have ''x''&thinsp;&isin;&thinsp;''O'' or ''x''<sup>&nbsp;-1</sup>&thinsp;&isin;&thinsp;''O''. Each such valuation ring is a [[discrete valuation ring]] and its maximal ideal is called a ''place'' of ''K''/''k''.
+Given an algebraic function field <math>K/k</math> of one variable, we define the notion of a ''valuation ring'' of <math>K/k</math>: this is a [[subring]] <math>\mathcal{O}</math> of <math>K</math> that contains <math>k</math> and is different from <math>k</math> and <math>K</math>, and such that for any <math>x</math> in <math>K</math> we have <math>x\in\mathcal{O}</math> or <math>x^{-1}\in\mathcal{O}</math>. Each such valuation ring is a [[discrete valuation ring]] and its maximal ideal is called a ''place'' of <math>K/k</math>.
-A ''discrete valuation'' of ''K''/''k'' is a [[surjective]] function ''v'' : ''K'' → '''Z'''∪{&infin;} such that ''v''(x)&thinsp;=&thinsp;&infin; iff ''x''&thinsp;=&thinsp;0, ''v''(''xy'') = ''v''(''x'')&thinsp;+&thinsp;''v''(''y'') and ''v''(''x''&thinsp;+&thinsp;''y'') ≥ min(''v''(''x''),''v''(''y'')) for all ''x'',&thinsp;''y''&thinsp;&isin;&thinsp;''K'', and ''v''(''a'')&thinsp;=&thinsp;0 for all ''a''&thinsp;&isin;&thinsp;''k''&thinsp;\&thinsp;{0}.
+A ''discrete valuation'' of <math>K/k</math> is a [[surjective]] function <math>v:K\to\Z\cup\{\infty\}</math> such that for all <math>x,y\in K</math>,
+* <math>v(xy)=v(x)+v(y)</math>,
+* <math>v(x+y)\geq \min\{v(x),v(y)\}</math>,
+* <math>v(x)=\infty \iff x=0</math>
+and <math>v(a)=0</math> for all <math>a\in k\setminus \{0\}</math>.
-There are natural bijective correspondences between the set of valuation rings of ''K''/''k'', the set of places of ''K''/''k'', and the set of discrete valuations of ''K''/''k''. These sets can be given a natural [[Topology|topological]] structure: the [[Zariski–Riemann space]] of ''K''/''k''.
+There are natural bijective correspondences between the set of valuation rings of <math>K/k</math>, the set of places of <math>K/k</math>, and the set of discrete valuations of <math>K/k</math>. These sets can be given a natural [[Topology|topological]] structure: the [[Zariski–Riemann space]] of <math>K/k</math>.
 ==See also==

Algebraic function field: Difference between revisions

Latest revision as of 23:58, 25 June 2025

Contents

Example

Category structure

Function fields arising from varieties, curves and Riemann surfaces

Number fields and finite fields

Field of constants

Valuations and places

See also

References

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Algebraic function field: Difference between revisions

Latest revision as of 23:58, 25 June 2025

Example

Category structure

Function fields arising from varieties, curves and Riemann surfaces

Number fields and finite fields

Field of constants

Valuations and places

See also

References

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