Ordered field: Difference between revisions

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It is possible for a field to have more than one linear order compatible with the field operations, but in any case the squares must lie in the positive cone.
It is possible for a field to have more than one linear order compatible with the field operations, but in any case the squares must lie in the positive cone.


A field ''F'' can be ordered if and only if -1 is not a sum of squares in ''F''.
==Artin-Schreier theorem==
A field ''F'' is '''formally real''' if -1 is not a sum of squares in ''F''.  The Artin-Schreier theorem states that a field ''F'' can be ordered if and only if it is formally real.


==Examples==
==Examples==
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* The complex numbers cannot be given an ordered field structure since both 1 and -1 are squares.
* The complex numbers cannot be given an ordered field structure since both 1 and -1 are squares.
* The [[quadratic field]] <math>\mathbf{Q}(\sqrt 2)</math> has two possible structures as ordered field, corresponding to the [[embedding]]s into '''R''' in which <math>\sqrt 2</math> takes on the two possible real values.
* The [[quadratic field]] <math>\mathbf{Q}(\sqrt 2)</math> has two possible structures as ordered field, corresponding to the [[embedding]]s into '''R''' in which <math>\sqrt 2</math> takes on the two possible real values.
* No [[finite field]] can be ordered.
* No [[finite field]] can be ordered.[[Category:Suggestion Bot Tag]]

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In mathematics, an ordered field is a field which has a linear order structure which is compatible with the field operations.

Formally, F is an ordered field if there is a linear order ≤ on F which satisfies

  • If then
  • For each element or ;
  • If and then

Alternatively, the order may be defined in terms of a positive cone, a subset C of F which is closed under addition and multiplication, contains the 0 and 1 elements, and which has the properties that

The relationship between the order and the associated positive cone is that

It is possible for a field to have more than one linear order compatible with the field operations, but in any case the squares must lie in the positive cone.

Artin-Schreier theorem

A field F is formally real if -1 is not a sum of squares in F. The Artin-Schreier theorem states that a field F can be ordered if and only if it is formally real.

Examples

  • The rational numbers form an ordered field in a unique way.
  • The real numbers form an ordered field in a unique way: the squares form the positive cone.
  • The complex numbers cannot be given an ordered field structure since both 1 and -1 are squares.
  • The quadratic field has two possible structures as ordered field, corresponding to the embeddings into R in which takes on the two possible real values.
  • No finite field can be ordered.