Difference between revisions of "ApCoCoA-1:Other5 groups"
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− | === <div id="Other5_groups">[[:ApCoCoA:Symbolic data#Other_groups|Other | + | === <div id="Other5_groups">[[:ApCoCoA:Symbolic data#Other_groups|Other Groups]]</div> === |
==== Description ==== | ==== Description ==== | ||
The first group, denoted by G, has an order |G| = 4224 and can be represented as: | The first group, denoted by G, has an order |G| = 4224 and can be represented as: |
Latest revision as of 21:09, 22 April 2014
Description
The first group, denoted by G, has an order |G| = 4224 and can be represented as:
G = <a,b | a^{2}b^{-4} = (ababab^{3})^{2} = 1>
The second group, denoted by H, is also solvable and has the following representation:
H = <a,b | a^{2}b^{4} = (ababab^{3})^{2} = 1>
Reference
No reference available
Computation of G
/*Use the ApCoCoA package ncpoly.*/ // a is invers to c and b is invers to d Use ZZ/(2)[a,b,c,d]; NC.SetOrdering("LLEX"); Define CreateRelationsOther5() Relations:=[]; // add the invers relations ac = ca = bd = db = 1 Append(Relations,[[a,c],[1]]); Append(Relations,[[c,a],[1]]); Append(Relations,[[b,d],[1]]); Append(Relations,[[d,b],[1]]); // add the relation a^{2}b^{-4} = 1 Append(Relations,[[a,a,d,d,d,d],[1]]); // add the relation (ababab^{3})^{2} = 1 Append(Relations,[[a,b,a,b,a,b,b,b,a,b,a,b,a,b,b,b],[1]]); Return Relations; EndDefine; Relations:=CreateRelationsOther5(); GB:=NC.GB(Relations,31,1,100,1000);
G in Symbolic Data Format
<FREEALGEBRA createdAt="2014-01-24" createdBy="strohmeier"> <vars>a,b,c,d</vars> <uptoDeg>12</uptoDeg> <basis> <ncpoly>a*c-1</ncpoly> <ncpoly>c*a-1</ncpoly> <ncpoly>b*d-1</ncpoly> <ncpoly>d*b-1</ncpoly> <ncpoly>a*a*d*d*d*d-1</ncpoly> <ncpoly>(a*b*a*b*a*b*b*b)^2-1</ncpoly> <Comment>relation:(ababab^{3})^{2} = 1</Comment> </basis> <Comment>The partial LLex Gb has 96 elements</Comment> <Comment>Other_groups5</Comment> </FREEALGEBRA>
Computation of H
/*Use the ApCoCoA package ncpoly.*/ // a is invers to c and b is invers to d Use ZZ/(2)[a,b,c,d]; NC.SetOrdering("LLEX"); Define CreateRelationsOther6() Relations:=[]; // add the invers relations ac = ca = bd = db = 1 Append(Relations,[[a,c],[1]]); Append(Relations,[[c,a],[1]]); Append(Relations,[[b,d],[1]]); Append(Relations,[[d,b],[1]]); // add the relation a^{2}b^{4} = 1 Append(Relations,[[a,a,b,b,b,b],[1]]); // add the relation (ababab^{3})^{2} = 1 Append(Relations,[[a,b,a,b,a,b,b,b,a,b,a,b,a,b,b,b],[1]]); Return Relations; EndDefine; Relations:=CreateRelationsOther6(); GB:=NC.GB(Relations,31,1,100,1000);
H in Symbolic Data Format
<FREEALGEBRA createdAt="2014-01-20" createdBy="strohmeier"> <vars>a,b,c,d</vars> <uptoDeg>13</uptoDeg> <basis> <ncpoly>a*c-1</ncpoly> <ncpoly>c*a-1</ncpoly> <ncpoly>b*d-1</ncpoly> <ncpoly>d*b-1</ncpoly> <Comment>polynomials to define inverse elements</Comment> <ncpoly>a*a*b*b*b*b-1</ncpoly> <ncpoly>(a*b*a*b*a*b*b*b)^2-1</ncpoly> <Comment>relation:(ababab^{3})^{2}= 1</Comment> </basis> <Comment>The partial LLex Gb has 268 elements</Comment> <Comment>Other_groups6</Comment> </FREEALGEBRA>