Field norm

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In mathematics, the (field) norm is a particular mapping defined in field theory, which maps elements of a larger field into a subfield.

Formal definition

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Let K be a field and L a finite extension (and hence an algebraic extension) of K.

The field L is then a finite-dimensional vector space over K.

Multiplication by α, an element of L,

 
 ,

is a K-linear transformation of this vector space into itself.

The norm, NL/K(α), is defined as the determinant of this linear transformation.[1]

If L/K is a Galois extension, one may compute the norm of αL as the product of all the Galois conjugates of α:

 

where Gal(L/K) denotes the Galois group of L/K.[2] (Note that there may be a repetition in the terms of the product.)


For a general field extension L/K, and nonzero α in L, let σ1(α), ..., σn(α) be the roots of the minimal polynomial of α over K (roots listed with multiplicity and lying in some extension field of L); then

 .


If L/K is separable, then each root appears only once in the product (though the exponent, the degree [L:K(α)], may still be greater than 1).

Examples

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Quadratic field extensions

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One of the basic examples of norms comes from quadratic field extensions   where   is a square-free integer.

Then, the multiplication map by   on an element   is

 

The element   can be represented by the vector

 

since there is a direct sum decomposition   as a  -vector space.

The matrix of   is then

 

and the norm is  , since it is the determinant of this matrix.


Norm of Q(√2)

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Consider the number field  .

The Galois group of   over   has order   and is generated by the element which sends   to  . So the norm of   is:

 


The field norm can also be obtained without the Galois group.

Fix a  -basis of  , say:

 .

Then multiplication by the number   sends

1 to   and
  to  .

So the determinant of "multiplying by  " is the determinant of the matrix which sends the vector

  (corresponding to the first basis element, i.e., 1) to  ,
  (corresponding to the second basis element, i.e.,  ) to  ,

viz.:

 

The determinant of this matrix is −1.

p-th root field extensions

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Another easy class of examples comes from field extensions of the form   where the prime factorization of   contains no  -th powers, for   a fixed odd prime.

The multiplication map by   of an element is

 

giving the matrix

 

The determinant gives the norm

 

Complex numbers over the reals

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The field norm from the complex numbers to the real numbers sends

x + iy

to

x2 + y2,

because the Galois group of   over   has two elements,

  • the identity element and
  • complex conjugation,

and taking the product yields (x + iy)(xiy) = x2 + y2.

Finite fields

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Let L = GF(qn) be a finite extension of a finite field K = GF(q).

Since L/K is a Galois extension, if α is in L, then the norm of α is the product of all the Galois conjugates of α, i.e.[3]

 

In this setting we have the additional properties,[4]

  •  
  •  

Properties of the norm

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Several properties of the norm function hold for any finite extension.[5][6]

Group homomorphism

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The norm NL/K : L* → K* is a group homomorphism from the multiplicative group of L to the multiplicative group of K, that is

 

Furthermore, if a in K:

 

If aK then  

Composition with field extensions

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Additionally, the norm behaves well in towers of fields:

if M is a finite extension of L, then the norm from M to K is just the composition of the norm from M to L with the norm from L to K, i.e.

 

Reduction of the norm

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The norm of an element in an arbitrary field extension can be reduced to an easier computation if the degree of the field extension is already known. This is

 [6]

For example, for   in the field extension  , the norm of   is

 

since the degree of the field extension   is  .

Detection of units

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For   the ring of integers of an algebraic number field  , an element   is a unit if and only if  .

For instance

 

where

 .

Thus, any number field   whose ring of integers   contains   has it as a unit.

Further properties

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The norm of an algebraic integer is again an integer, because it is equal (up to sign) to the constant term of the characteristic polynomial.

In algebraic number theory one defines also norms for ideals. This is done in such a way that if I is a nonzero ideal of OK, the ring of integers of the number field K, N(I) is the number of residue classes in   – i.e. the cardinality of this finite ring. Hence this ideal norm is always a positive integer.

When I is a principal ideal αOK then N(I) is equal to the absolute value of the norm to Q of α, for α an algebraic integer.

See also

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Notes

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  1. ^ Rotman 2002, p. 940
  2. ^ Rotman 2002, p. 943
  3. ^ Lidl & Niederreiter 1997, p. 57
  4. ^ Mullen & Panario 2013, p. 21
  5. ^ Roman 2006, p. 151
  6. ^ a b Oggier. Introduction to Algebraic Number Theory (PDF). p. 15. Archived from the original (PDF) on 2014-10-23. Retrieved 2020-03-28.

References

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