Home Online Manual
Top
Back: getVariableWeights
Forward: getLattice
FastBack:
FastForward:
Up: multigrading_lib
Top: Singular Manual
Contents: Table of Contents
Index: Index
About: About this document

D.15.11.3 getGradingGroup

Procedure from library multigrading.lib (see multigrading_lib).

Usage:
getGradingGroup([R])

Purpose:
get associated grading group

Return:
group, the grading group

Example:
 
LIB "multigrading.lib";
ring R = 0, (x, y, z), dp;
// Weights of variables
intmat M[3][3] =
1, 0, 0,
0, 1, 0,
0, 0, 1;
// Torsion:
intmat L[3][2] =
1, 1,
1, 3,
1, 5;
// attaches M & L to R (==basering):
setBaseMultigrading(M, L); // Grading: Z^3/L
def G = getGradingGroup();
printGroup( G );
==> Generators: 
==>      1     0     0
==>      0     1     0
==>      0     0     1
==> Relations: 
==>      1     1
==>      1     3
==>      1     5
G[1] == M; G[2] == L;
==> 1
==> 1
kill L, M, G;
// ----------- isomorphic multigrading -------- //
// Weights of variables
intmat M[2][3] =
1, -2, 1,
1,  1, 0;
// Torsion:
intmat L[2][1] =
0,
2;
// attaches M & L to R (==basering):
setBaseMultigrading(M, L); // Grading: Z + (Z/2Z)
def G = getGradingGroup();
printGroup( G );
==> Generators: 
==>      1    -2     1
==>      1     1     0
==> Relations: 
==>      0
==>      2
G[1] == M; G[2] == L;
==> 1
==> 1
kill L, M, G;
// ----------- extreme case ------------ //
// Weights of variables
intmat M[1][3] =
1,  -1, 10;
// Torsion:
intmat L[1][1] =
0;
// attaches M & L to R (==basering):
setBaseMultigrading(M); // Grading: Z^3
def G = getGradingGroup();
printGroup( G );
==> Generators: 
==>      1    -1    10
==> Relations: 
==>      0
G[1] == M; G[2] == L;
==> 1
==> 1
kill L, M, G;