Difference between revisions of "ApCoCoA-1:Higman groups"
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| − | === <div id="Higman_groups">[[:ApCoCoA:Symbolic data#Higman_group|Higman | + | === <div id="Higman_groups">[[:ApCoCoA:Symbolic data#Higman_group|Higman Group]]</div> === |
==== Description ==== | ==== Description ==== | ||
The Higman group is an infinite finitely presented group with no non-trivial finite quotients and is generated by the | The Higman group is an infinite finitely presented group with no non-trivial finite quotients and is generated by the | ||
| Line 49: | Line 49: | ||
Gb; | Gb; | ||
Size(Gb); | Size(Gb); | ||
| + | |||
| + | ====Example in Symbolic Data Format==== | ||
| + | <FREEALGEBRA createdAt="2014-01-20" createdBy="strohmeier"> | ||
| + | <vars>a,b,c,d,e,f,g,h</vars> | ||
| + | <uptoDeg>5</uptoDeg> | ||
| + | <basis> | ||
| + | <ncpoly>a*e-1</ncpoly> | ||
| + | <ncpoly>e*a-1</ncpoly> | ||
| + | <ncpoly>b*f-1</ncpoly> | ||
| + | <ncpoly>f*b-1</ncpoly> | ||
| + | <ncpoly>c*g-1</ncpoly> | ||
| + | <ncpoly>g*c-1</ncpoly> | ||
| + | <ncpoly>d*h-1</ncpoly> | ||
| + | <ncpoly>h*d-1</ncpoly> | ||
| + | <ncpoly>e*b*a-b*b</ncpoly> | ||
| + | <ncpoly>f*c*b-c*c</ncpoly> | ||
| + | <ncpoly>g*d*c-d*d</ncpoly> | ||
| + | <ncpoly>h*a*d-a*a</ncpoly> | ||
| + | </basis> | ||
| + | <Comment>The partial LLex Gb has 144 elements</Comment> | ||
| + | <Comment>Higman_group</Comment> | ||
| + | </FREEALGEBRA> | ||
Latest revision as of 20:50, 22 April 2014
Description
The Higman group is an infinite finitely presented group with no non-trivial finite quotients and is generated by the elements a,b,c and d with the following relations:
H = <a,b,c,d | a^{-1}ba = b^{2}, b^{-1}cb = c^{2}, c^{-1}dc = d^{2}, d^{-1}ad = a^{2}>
Reference
Graham Higman, "A finitely generated infinite simple group", Journal of the London Mathematical Society. Second Series 26 (1): 61–64, 1951.
Computation
/*Use the ApCoCoA package ncpoly.*/
// a is inverse to e, b is inverse to f, c is inverse to g and d is inverse to h
Use ZZ/(2)[a,b,c,d,e,f,g,h];
NC.SetOrdering("LLEX");
Define CreateRelationsHigman()
Relations:=[];
// add the relations of the inverse elements
Append(Relations,[[a,e],[1]]);
Append(Relations,[[e,a],[1]]);
Append(Relations,[[b,f],[1]]);
Append(Relations,[[f,b],[1]]);
Append(Relations,[[c,g],[1]]);
Append(Relations,[[g,c],[1]]);
Append(Relations,[[d,h],[1]]);
Append(Relations,[[h,d],[1]]);
// add the relation a^{-1}ba = b^2
Append(Relations,[[e,b,a],[b^2]]);
// add the relation b^{-1}cb = c^2
Append(Relations,[[f,c,b],[c^2]]);
// add the relation c^{-1}dc = d^2
Append(Relations, [[g,d,c],[d^2]]);
// add the relation d^{-1}ad = a^2
Append(Relations, [[h,a,d],[a^2]]);
Return Relations;
EndDefine;
Relations:=CreateRelationsHigman();
Relations;
Gb:=NC.GB(Relations,31,1,100,1000);
Gb;
Size(Gb);
Example in Symbolic Data Format
<FREEALGEBRA createdAt="2014-01-20" createdBy="strohmeier"> <vars>a,b,c,d,e,f,g,h</vars> <uptoDeg>5</uptoDeg> <basis> <ncpoly>a*e-1</ncpoly> <ncpoly>e*a-1</ncpoly> <ncpoly>b*f-1</ncpoly> <ncpoly>f*b-1</ncpoly> <ncpoly>c*g-1</ncpoly> <ncpoly>g*c-1</ncpoly> <ncpoly>d*h-1</ncpoly> <ncpoly>h*d-1</ncpoly> <ncpoly>e*b*a-b*b</ncpoly> <ncpoly>f*c*b-c*c</ncpoly> <ncpoly>g*d*c-d*d</ncpoly> <ncpoly>h*a*d-a*a</ncpoly> </basis> <Comment>The partial LLex Gb has 144 elements</Comment> <Comment>Higman_group</Comment> </FREEALGEBRA>
