Difference between revisions of "ApCoCoA-1:BBSGen.TraceSyzFull"
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</syntax> | </syntax> | ||
<description> | <description> | ||
− | Let l,k_{1},....,k_{s} | + | Let l,k_{1},....,k_{s} in {1,...,n} with s in N^{+} and |
Pi=x_{k_{1}}...x_{k_{s}}x_{l} | Pi=x_{k_{1}}...x_{k_{s}}x_{l} | ||
− | a term (or power product) from the given Ring K[x_1,...,x_N]. Let the generic multiplication matrices A_{k_{1}},...,A_{k_{s}},A_{l} | + | a term (or power product) from the given Ring K[x_1,...,x_N]. Let the generic multiplication matrices A_{k_{1}},...,A_{k_{s}},A_{l} in Mat(K[c]) be associated to the indeterminates in Pi. We shall name the polynomial |
− | Trace([A_{k_{1}}...A_{k_{s}},A_{l}]) | + | Trace([A_{k_{1}}...A_{k_{s}},A_{l}]) in K[c] |
as the trace polynomial with respect to Pi and variable x_{l}. We shall denote it by | as the trace polynomial with respect to Pi and variable x_{l}. We shall denote it by | ||
T_{Pi,x_{l}}}. | T_{Pi,x_{l}}}. | ||
− | This function computes every trace polynomial with respect to every Pi that is equal to a non-standard degree of an element from | + | This function computes every trace polynomial with respect to every Pi with log that is equal to a non-standard degree of an element from tau and with respect to every variable from {x_1,...,x_N}. |
NOTE: This function due to the growth of polynomials during the matrix multiplication, may not give result for every ring and order ideal. In that case we recommend <ref>BBSGen.TraceSyzStep</ref> and | NOTE: This function due to the growth of polynomials during the matrix multiplication, may not give result for every ring and order ideal. In that case we recommend <ref>BBSGen.TraceSyzStep</ref> and |
Revision as of 15:16, 18 June 2012
BBSGen.TraceSyzFull
This function computes the trace polynomials.
Syntax
TraceSyzFull(OO,BO,N); TraceSyzFull(OO:LIST,BO:LIST,N:INTEGER):LIST
Description
Let l,k_{1},....,k_{s} in {1,...,n} with s in N^{+} and
Pi=x_{k_{1}}...x_{k_{s}}x_{l}
a term (or power product) from the given Ring K[x_1,...,x_N]. Let the generic multiplication matrices A_{k_{1}},...,A_{k_{s}},A_{l} in Mat(K[c]) be associated to the indeterminates in Pi. We shall name the polynomial
Trace([A_{k_{1}}...A_{k_{s}},A_{l}]) in K[c]
as the trace polynomial with respect to Pi and variable x_{l}. We shall denote it by
T_{Pi,x_{l}}}.
This function computes every trace polynomial with respect to every Pi with log that is equal to a non-standard degree of an element from tau and with respect to every variable from {x_1,...,x_N}.
NOTE: This function due to the growth of polynomials during the matrix multiplication, may not give result for every ring and order ideal. In that case we recommend BBSGen.TraceSyzStep and
@param The order ideal OO, border BO, the number of indeterminates of the polynomial ring K[x_1,...,x_N].
@return The list of Trace Syzygy polynomials.
Example
Use R::=QQ[x[1..2]]; OO:=$apcocoa/borderbasis.Box([1,1]); BO:=$apcocoa/borderbasis.Border(OO); N:=Len(Indets()); W:=BBSGen.Wmat(OO,BO,N); Mu:=Len(OO); Nu:=Len(BO); Use XX::=QQ[c[1..Mu,1..Nu],t[1..N,1..N,1..Mu,1..Mu]]; BBSGen.TraceSyzFull(OO,BO,N); [c[1,2]t[1,2,3,1] + c[2,2]t[1,2,3,2] + c[3,2]t[1,2,3,3] + c[4,2]t[1,2,3,4] + c[1,4]t[1,2,4,1] + c[2,4]t[1,2,4,2] + c[3,4]t[1,2,4,3] + c[4,4]t[1,2,4,4] + t[1,2,1,3] + t[1,2,2,4], 2c[1,1]t[1,2,2,1] + 2c[2,1]t[1,2,2,2] + 2c[3,1]t[1,2,2,3] + 2c[4,1]t[1,2,2,4]+ 2c[1,3]t[1,2,4,1] + 2c[2,3]t[1,2,4,2] + 2c[3,3]t[1,2,4,3] + 2c[4,3]t[1,2,4,4] + 2t[1,2,1,2] + 2t[1,2,3,4], c[1,2]t[1,2,3,1] + c[2,2]t[1,2,3,2] + c[3,2]t[1,2,3,3] + c[4,2]t[1,2,3,4] + c[1,4]t[1,2,4,1] + c[2,4]t[1,2,4,2] + c[3,4]t[1,2,4,3] + c[4,4]t[1,2,4,4] + t[1,2,1,3] + t[1,2,2,4], 2c[1,2]c[3,1]t[1,2,2,1] + 2c[1,4]c[4,1]t[1,2,2,1] + 2c[2,2]c[3,1]t[1,2,2,2] + 2c[2,4]c[4,1]t[1,2,2,2] + 2c[3,1]c[3,2]t[1,2,2,3] + 2c[3,4]c[4,1]t[1,2,2,3] + 2c[3,1]c[4,2]t[1,2,2,4] + 2c[4,1]c[4,4]t[1,2,2,4] + 2c[1,2]c[3,3]t[1,2,4,1] + 2c[1,4]c[4,3]t[1,2,4,1] + 2c[2,2]c[3,3]t[1,2,4,2] + 2c[2,4]c[4,3]t[1,2,4,2] + 2c[3,2]c[3,3]t[1,2,4,3] + 2c[3,4]c[4,3]t[1,2,4,3] + 2c[3,3]c[4,2]t[1,2,4,4] + 2c[4,3]c[4,4]t[1,2,4,4] + 2c[1,1]t[1,2,2,3] + 2c[2,1]t[1,2,2,4] + 2c[1,4]t[1,2,3,1] + 2c[2,4]t[1,2,3,2] + 2c[3,4]t[1,2,3,3] + 2c[4,4]t[1,2,3,4] + 2c[1,3]t[1,2,4,3] + 2c[2,3]t[1,2,4,4] + 2t[1,2,1,4]]