gap> ######################### BEGIN COPYRIGHT MESSAGE #########################
GBNP - computing Gröbner bases of noncommutative polynomials
Copyright 2001-2010 by Arjeh M. Cohen, Dié A.H. Gijsbers, Jan Willem
Knopper, Chris Krook. Address: Discrete Algebra and Geometry (DAM) group
at the Department of Mathematics and Computer Science of Eindhoven
University of Technology.
For acknowledgements see the manual. The manual can be found in several
formats in the doc subdirectory of the GBNP distribution. The
acknowledgements formatted as text can be found in the file chap0.txt.
GBNP is free software; you can redistribute it and/or modify it under
the terms of the Lesser GNU General Public License as published by the
Free Software Foundation (FSF); either version 2.1 of the License, or
(at your option) any later version. For details, see the file 'LGPL' in
the doc subdirectory of the GBNP distribution or see the FSF's own site: https://www.gnu.org/licenses/lgpl.html
gap> ########################## END COPYRIGHT MESSAGE ##########################
gap> ### filename = "example16.g"
gap> ### authors Cohen & Gijsbers & Krook
gap>
gap> ### THIS IS A GAP PACKAGE GBNP
gap> ### FOR COMPUTING WITH NON-COMMUTATIVE POLYNOMIALS
gap> ### ADD-ON: STUDY GROWTH OF FACTOR ALGEBRA
<#GAPDoc Label="Example16">
<Section Label="Example16"><Heading>A commutative quotient algebra of polynomial growth</Heading>
This example extends <Ref Sect="Example06"/>,
a commutative example from Some Tapas of Computer Algebra <Cite
Key="CohenCuypersSterk1999"/>, page 339.
<P/>
The result of the Gröbner basis computation
should be the union of <M>\{a,b\}</M> and
the set of 6 homogeneous binomials
(that is, polynomials with two terms) of degree 2 forcing
commuting between <M>c</M>, <M>d</M>, <M>e</M>, and <M>f</M>, as before.
After computation of the Gröbner basis, the quotient algebra is studied and
found to be infinite dimensional of polynomial growth of degree 4. The
function <Ref Func="DetermineGrowthQA" Style="Text"/> is used for this
computation. Then part of its Hilbert series is computed. The function <Ref
Func="HilbertSeriesQA" Style="Text"/> is used for the computations.
<P/>
First load the package and set the standard infolevel <Ref
InfoClass="InfoGBNP" Style="Text"/> to 2 and the time infolevel <Ref
Func="InfoGBNPTime" Style="Text"/> to 1 (for more information about the info
level, see Chapter <Ref Chap="Info"/>).
Now define some functions which will help in the construction of relations.
The function <C>powermon(i, exp)</C> will return the monomial <M>i^{exp}</M>.
The function <C>comm(aa, bb)</C> will return a relation forcing commutativity
between its two arguments <C>aa</C> and <C>bb</C>.
<Listing><![CDATA[
gap> powermon := function(base, exp)
> local ans,i;
> ans := [];
> for i in [1..exp] do ans := Concatenation(ans,[base]); od;
> return ans;
> end;;
gap> comm := function(aa,bb)
> return [[[aa,bb],[bb,aa]],[1,-1]];
> end;;
]]></Listing>
The relations can be shown with <Ref Func="PrintNPList" Style="Text"/>:
<Listing><![CDATA[
gap> PrintNPList(KI);
ea
a^3 + fa
a^9 + ca^3
a^81 + ca^9 + da^3
ca^81 + da^9 + ea^3
a^27 + da^81 + ea^9 + fa^3
b + ca^27 + ea^81 + fa^9
cb + da^27 + fa^81
a + db + ea^27
ca + eb + fa^27
da + fb
b^3 - b
ab - ba
ac - ca
ad - da
ae - ea
af - fa
bc - cb
bd - db
be - eb
bf - fb
cd - dc
ce - ec
cf - fc
de - ed
df - fd
ef - fe
]]></Listing>
It is usually easier to use the function <Ref Func="GP2NP" Style="Text"/> or
the function <Ref Func="GP2NPList" Style="Text"/> to enter relations.
Entering the first twelve relations and then converting them with <Ref
Func="GP2NPList" Style="Text"/> is demonstrated in example 6 (<Ref
Sect="Example06"/>). More about converting can be read in Section <Ref
Sect="TransitionFunctions"/>.
<P/>
The Gröbner basis can now be calculated with <Ref Func="SGrobner"
Style="Text"/> and printed with <Ref Func="PrintNPList" Style="Text"/>.
<Listing><![CDATA[
gap> GB := SGrobner(KI);
#I number of entered polynomials is 27
#I number of polynomials after reduction is 8
#I End of phase I
#I End of phase II
#I List of todo lengths is [ 0 ]
#I End of phase III
#I G: Cleaning finished, 0 polynomials reduced
#I End of phase IV
#I The computation took 728 msecs.
[ [ [ [ 1 ] ], [ 1 ] ], [ [ [ 2 ] ], [ 1 ] ],
[ [ [ 4, 3 ], [ 3, 4 ] ], [ 1, -1 ] ], [ [ [ 5, 3 ], [ 3, 5 ] ], [ 1, -1 ] ]
, [ [ [ 5, 4 ], [ 4, 5 ] ], [ 1, -1 ] ],
[ [ [ 6, 3 ], [ 3, 6 ] ], [ 1, -1 ] ], [ [ [ 6, 4 ], [ 4, 6 ] ], [ 1, -1 ] ]
, [ [ [ 6, 5 ], [ 5, 6 ] ], [ 1, -1 ] ] ]
gap> PrintNPList(GB);
a
b
dc - cd
ec - ce
ed - de
fc - cf
fd - df
fe - ef
]]></Listing>
The growth of the quotient algebra can be studied with <Ref
Func="DetermineGrowthQA" Style="Text"/>. The first argument is the list
of leading
monomials, which can be calculated with <Ref Func="LMonsNP" Style="Text"/>.
The second argument is the size of the alphabet.
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nach bestem Wissen sorgfältig zusammengestellt. Es wird jedoch weder Vollständigkeit, noch Richtigkeit,
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