Difference between revisions of "ApCoCoA-1:CharP.GBasisF4"

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This command computes a Groebner basis in the field <formula> \mathbb{F}_{4} = (\mathbb{Z}_{\setminus(2)} [x])_{\setminus(x^2 + x +1)}</formula>. It uses the ApCoCoA Server and the ApCoCoALib's class [[ApCoCoALib:RingF4|RingF4]].  
 
This command computes a Groebner basis in the field <formula> \mathbb{F}_{4} = (\mathbb{Z}_{\setminus(2)} [x])_{\setminus(x^2 + x +1)}</formula>. It uses the ApCoCoA Server and the ApCoCoALib's class [[ApCoCoALib:RingF4|RingF4]].  
  

Revision as of 14:02, 14 November 2008

Char2.GBasisF4

computing a gbasis of a given ideal in <formula>\mathbb{F}_{4}</formula>

Syntax

$char2.GBasisF4(Ideal):List

Description

Please note: The function(s) explained on this page is/are using the ApCoCoAServer. You will have to start the ApCoCoAServer in order to use

it/them.

This command computes a Groebner basis in the field <formula> \mathbb{F}_{4} = (\mathbb{Z}_{\setminus(2)} [x])_{\setminus(x^2 + x +1)}</formula>. It uses the ApCoCoA Server and the ApCoCoALib's class RingF4.

The command's input is a an Ideal in a Ring over Z, where the elements 0,..., 3 represent the field's elements. Details on this representation can be found here. For short, the binary representation of the number represents the coefficient vector if the polynomial in the field, e.g.

<formula> 11 = 8 + 2 + 1 = 2^3 + 2^1 + 2^0</formula>

So the number <formula>11</formula> corresponds to the polynomial <formula>x^3 + x + 1</formula>.


See also

GBasis

char2.GBasisF2

char2.GBasisF8

char2.GBasisF16

char2.GBasisF32

char2.GBasisF64

char2.GBasisF128

char2.GBasisF256

char2.GBasisF512

char2.GBasisF1024

char2.GBasisF2048

char2.GBasisF4096

char2.GBasisModSquares