Relative finite field extension and element computations

asked 2016-11-18 10:19:10 +0200

Johan
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updated 2019-08-29 18:24:44 +0200

FrédéricC

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Hallo

I want to perform finite field multiplication in by using operation in one of its sub fields.

f4 = GF(4, 'x')
f16 =  GF(16, 'y')
ff = RelativeFiniteFieldExtension(f16, f4)

Now I am stuck:

How do I map element from ff to a vector over f4
After performing the computation in f4 map the element back in f?

The ideal will be that the mapping to ff just concatenate two element in f4.

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Where does RelativeFiniteFieldExtension comes from ?

tmonteil ( 2016-11-18 12:03:31 +0200 )edit

Probably from coding theory.

sage: from sage.coding.relative_finite_field_extension import RelativeFiniteFieldExtension
sage: RelativeFiniteFieldExtension
<class 'sage.coding.relative_finite_field_extension.RelativeFiniteFieldExtension'>

slelievre ( 2016-11-18 17:02:31 +0200 )edit

@ slelievre, Yes

Johan ( 2016-11-21 20:49:11 +0200 )edit

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answered 2016-11-18 17:13:48 +0200

slelievre
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updated 2016-11-22 09:52:26 +0200

Is this what you are looking for?

Import RelativeFiniteFieldExtension and define the fields and the relative finite field extension.

sage: from sage.coding.relative_finite_field_extension import RelativeFiniteFieldExtension
sage: f4 = GF(4, 'x')
sage: f16 = GF(16, 'y')
sage: ff = RelativeFiniteFieldExtension(f16, f4)
sage: ff.embedding()
Ring morphism:
  From: Finite Field in x of size 2^2
  To:   Finite Field in y of size 2^4
  Defn: x |--> y^2 + y

Apply to a vector.

sage: V = VectorSpace(f4, 2)
sage: v = V.random_element(); v
(x, x + 1)
sage: v.apply_map(ff.embedding())
(y^2 + y, y^2 + y + 1)

Edit: the absolute_field_representation and relative_field_reprensentation methods may be what you are looking for.

They are documented here:

Following and expanding the examples from the documentation and adapting to your notation.

sage: from sage.coding.relative_finite_field_extension import RelativeFiniteFieldExtension
sage: f4.<x> = GF(4)
sage: f16.<y> = GF(16)
sage: ff = RelativeFiniteFieldExtension(f16, f4)
sage: b = y^3 + y^2 + y + 1
sage: bb = ff.relative_field_representation(b)
sage: bb
(1, x + 1)
sage: bb.parent()
Vector space of dimension 2 over Finite Field in x of size 2^2
sage: ff.absolute_field_representation(bb)
y^3 + y^2 + y + 1

sage: V = VectorSpace(f4, 2)
sage: cc = V((x, x+1))
sage: cc
(x, x + 1)
sage: c = ff.absolute_field_representation(cc)
sage: c
y^3
sage: c.parent()
Finite Field in y of size 2^4
sage: ff.relative_field_representation(c)
sage: ff.relative_field_representation(c)
(x, x + 1)

This shows the isomorphism you want, going both ways.

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Almost, v.apply_map(ff.embedding()) give an element in VectorSpace(f16,2). I want an element in f16, an isomorphism from VectorSpace(f4,2) to VectorSpace(f16,2). The purpose will be to verify an implementation of a finite field (f16) using a subfield (f4) for its computations.

Johan ( 2016-11-21 20:53:53 +0200 )edit

I edited my answer with isomorphisms going both ways between VectorSpace(f4, 2) and f16.

slelievre ( 2016-11-22 09:53:57 +0200 )edit

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Relative finite field extension and element computations

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