| version 1.5, 2003/08/04 11:42:42 |
version 1.9, 2003/08/22 23:55:21 |
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| % $OpenXM: OpenXM/src/kan96xx/Doc/ecart.sm1,v 1.4 2003/07/30 09:00:51 takayama Exp $ |
% $OpenXM: OpenXM/src/kan96xx/Doc/ecart.sm1,v 1.8 2003/08/21 12:28:58 takayama Exp $ |
| %[(parse) (hol.sm1) pushfile] extension |
%[(parse) (hol.sm1) pushfile] extension |
| %[(parse) (appell.sm1) pushfile] extension |
%[(parse) (appell.sm1) pushfile] extension |
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| /ecart.end { endEcart } def |
/ecart.end { endEcart } def |
| /ecart.autoHomogenize 1 def |
/ecart.autoHomogenize 1 def |
| /ecart.needSyz 0 def |
/ecart.needSyz 0 def |
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/ecartd.begin { |
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ecart.begin |
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[(EcartAutomaticHomogenization) 1] system_variable |
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} def |
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/ecartd.end { |
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ecart.end |
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[(EcartAutomaticHomogenization) 0] system_variable |
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} def |
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| /ecart.dehomogenize { |
/ecart.dehomogenize { |
| /arg1 set |
/arg1 set |
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| arg1 |
arg1 |
| } def |
} def |
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/ecart.gb {ecartd.gb} def |
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[(ecart.gb) |
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[(a ecart.gb b) |
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(array a; array b;) |
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$b : [g ii]; array g; array in; g is a standard (Grobner) basis of f$ |
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( in the ring of differential operators.) |
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(The computation is done by using Ecart division algorithm and ) |
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(the double homogenization.) |
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(cf. M.Granger and T.Oaku: Minimal filtered free resolutions ... 2003) |
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$ ii is the initial ideal in case of w is given or <<a>> belongs$ |
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$ to a ring. In the other cases, it returns the initial monominal.$ |
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(a : [f ]; array f; f is a set of generators of an ideal in a ring.) |
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(a : [f v]; array f; string v; v is the variables. ) |
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(a : [f v w]; array f; string v; array of array w; w is the weight matirx.) |
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(a : [f v w ds]; array f; string v; array of array w; w is the weight matirx.) |
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( array ds; ds is the degree shift ) |
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( ) |
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$cf. ecarth.gb (homogenized), ecartd.gb (dehomogenize) $ |
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( ) |
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$Example 1: [ [( (x Dx)^2 + (y Dy)^2 -1) ( x y Dx Dy -1)] (x,y) $ |
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$ [ [ (Dx) 1 ] [(x) -1 (y) -1 (Dx) 1 (Dy) 1]] ] ecart.gb pmat ; $ |
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(Example 2: ) |
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$ [ [(2 x Dx + 3 y Dy+6) (2 y Dx + 3 x^2 Dy)] (x,y) $ |
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$ [[(x) -1 (Dx) 1 (y) -1 (Dy) 1]]] ecart.gb /ff set ff pmat ;$ |
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(To set the current ring to the ring in which ff belongs ) |
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( ff getRing ring_def ) |
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( ) |
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$Example 3: [ [( (x Dx)^2 + (y Dy)^2 -1) ( x y Dx Dy -1)] (x,y) $ |
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$ [ [ (Dx) 1 (Dy) 1] ] ] ecart.gb pmat ; $ |
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( ) |
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$Example 4: [[ [(x^2) (y+x)] [(x+y) (y^3)] [(2 x^2+x y) (y+x+x y^3)]] (x,y) $ |
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$ [ [ (x) -1 (y) -1] [(x) -1 (y) -1 (Dx) 1 (Dy) 1]] ] ecart.gb pmat ; $ |
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( ) |
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$Example 5: [[ [(x^2) (y+x)] [(x+y) (y^3)] [(2 x^2+x y) (y+x+x y^3)]] (x,y) $ |
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$ [ [(Dx) 1 (Dy) 1] [(x) -1 (y) -1 (Dx) 1 (Dy) 1] ] [[0 1] [-3 1] ] ] ecart.gb pmat ; $ |
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( ) |
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(cf. gb, groebner, ecarth.gb, ecartd.gb, ecart.syz, ecart.begin, ecart.end, ecart.homogenize01, ) |
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( ecart.dehomogenize, ecart.dehomogenizeH) |
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( [(weightedHomogenization) 1 (degreeShift) [[1 2 1]]] : options for ) |
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( define_ring ) |
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(/ecart.autoHomogenize 0 def ) |
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( not to dehomogenize and homogenize) |
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]] putUsages |
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| /ecart.gb.verbose 1 def |
/ecart.gb.verbose 1 def |
| /ecart.gb { |
/ecarth.gb { |
| /arg1 set |
/arg1 set |
| [/in-ecart.gb /aa /typev /setarg /f /v |
[/in-ecarth.gb /aa /typev /setarg /f /v |
| /gg /wv /vec /ans /rr /mm |
/gg /wv /vec /ans /rr /mm |
| /degreeShift /env2 /opt /ans.gb |
/degreeShift /env2 /opt /ans.gb |
| ] pushVariables |
] pushVariables |
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| } { } ifelse |
} { } ifelse |
| wv isInteger { |
wv isInteger { |
| [v ring_of_differential_operators |
[v ring_of_differential_operators |
| [ v ecart.wv1 v ecart.wv2 ] weight_vector |
% [ v ecart.wv1 v ecart.wv2 ] weight_vector |
| gb.characteristic |
gb.characteristic |
| opt |
opt |
| ] define_ring |
] define_ring |
| }{ |
}{ |
| degreeShift isInteger { |
degreeShift isInteger { |
| [v ring_of_differential_operators |
[v ring_of_differential_operators |
| [v ecart.wv1 v ecart.wv2] wv join weight_vector |
% [v ecart.wv1 v ecart.wv2] wv join weight_vector |
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wv weight_vector |
| gb.characteristic |
gb.characteristic |
| opt |
opt |
| ] define_ring |
] define_ring |
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| }{ |
}{ |
| [v ring_of_differential_operators |
[v ring_of_differential_operators |
| [v ecart.wv1 v ecart.wv2] wv join weight_vector |
% [v ecart.wv1 v ecart.wv2] wv join weight_vector |
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wv weight_vector |
| gb.characteristic |
gb.characteristic |
| [(degreeShift) degreeShift] opt join |
[(degreeShift) degreeShift] opt join |
| ] define_ring |
] define_ring |
|
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| %%% Enf of the preprocess |
%%% Enf of the preprocess |
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| ecart.gb.verbose { |
ecart.gb.verbose { |
| (The first and the second weight vectors are automatically set as follows) |
(The first and the second weight vectors for automatic homogenization: ) |
| message |
message |
| v ecart.wv1 message |
v ecart.wv1 message |
| v ecart.wv2 message |
v ecart.wv2 message |
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| popVariables |
popVariables |
| arg1 |
arg1 |
| } def |
} def |
| (ecart.gb ) messagen-quiet |
(ecarth.gb ) messagen-quiet |
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| [(ecart.gb) |
[(ecarth.gb) |
| [(a ecart.gb b) |
[(a ecarth.gb b) |
| (array a; array b;) |
(array a; array b;) |
| $b : [g ii]; array g; array in; g is a standard (Grobner) basis of f$ |
$b : [g ii]; array g; array in; g is a standard (Grobner) basis of f$ |
| ( in the ring of differential operators.) |
( in the ring of differential operators.) |
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| ( not to dehomogenize and homogenize) |
( not to dehomogenize and homogenize) |
| ( ) |
( ) |
| $Example 1: [ [( (x Dx)^2 + (y Dy)^2 -1) ( x y Dx Dy -1)] (x,y) $ |
$Example 1: [ [( (x Dx)^2 + (y Dy)^2 -1) ( x y Dx Dy -1)] (x,y) $ |
| $ [ [ (Dx) 1 ] ] ] ecart.gb pmat ; $ |
$ [ [ (Dx) 1 ] [(x) -1 (y) -1 (Dx) 1 (Dy) 1]] ] ecarth.gb pmat ; $ |
| (Example 2: ) |
(Example 2: ) |
| (To put H and h=1, type in, e.g., ) |
(To put H and h=1, type in, e.g., ) |
| $ [ [(2 x Dx + 3 y Dy+6) (2 y Dx + 3 x^2 Dy)] (x,y) $ |
$ [ [(2 x Dx + 3 y Dy+6) (2 y Dx + 3 x^2 Dy)] (x,y) $ |
| $ [[(x) -1 (Dx) 1 (y) -1 (Dy) 1]]] ecart.gb /gg set gg ecart.dehomogenize pmat ;$ |
$ [[(x) -1 (Dx) 1 (y) -1 (Dy) 1]]] ecarth.gb /gg set gg ecart.dehomogenize pmat ;$ |
| ( ) |
( ) |
| $Example 3: [ [( (x Dx)^2 + (y Dy)^2 -1) ( x y Dx Dy -1)] (x,y) $ |
$Example 3: [ [( (x Dx)^2 + (y Dy)^2 -1) ( x y Dx Dy -1)] (x,y) $ |
| $ [ [ (Dx) 1 (Dy) 1] ] ] ecart.gb pmat ; $ |
$ [ [ (Dx) 1 (Dy) 1] ] ] ecarth.gb pmat ; $ |
| ( ) |
( ) |
| $Example 4: [[ [(x^2) (y+x)] [(x+y) (y^3)] [(2 x^2+x y) (y+x+x y^3)]] (x,y) $ |
$Example 4: [[ [(x^2) (y+x)] [(x+y) (y^3)] [(2 x^2+x y) (y+x+x y^3)]] (x,y) $ |
| $ [ [ (x) -1 (y) -1] ] ] ecart.gb pmat ; $ |
$ [ [ (x) -1 (y) -1] [(x) -1 (y) -1 (Dx) 1 (Dy) 1]] ] ecarth.gb pmat ; $ |
| ( ) |
( ) |
| $Example 5: [[ [(x^2) (y+x)] [(x+y) (y^3)] [(2 x^2+x y) (y+x+x y^3)]] (x,y) $ |
$Example 5: [[ [(x^2) (y+x)] [(x+y) (y^3)] [(2 x^2+x y) (y+x+x y^3)]] (x,y) $ |
| $ [ [ (x) -1 (y) -1] ] [[0 1] [-3 1] ] ] ecart.gb pmat ; $ |
$ [ [(Dx) 1 (Dy) 1] [(x) -1 (y) -1 (Dx) 1 (Dy) 1] ] [[0 1] [-3 1] ] ] ecarth.gb pmat ; (buggy infinite loop)$ |
| ( ) |
( ) |
| (cf. gb, groebner, ecart.syz, ecart.begin, ecart.end, ecart.homogenize01, ) |
(cf. gb, groebner, ecart.gb, ecartd.gb, ecart.syz, ecart.begin, ecart.end, ecart.homogenize01, ) |
| ( ecart.dehomogenize, ecart.dehomogenizeH) |
( ecart.dehomogenize, ecart.dehomogenizeH) |
| ( [(weightedHomogenization) 1 (degreeShift) [[1 2 1]]] : options for ) |
( [(weightedHomogenization) 1 (degreeShift) [[1 2 1]]] : options for ) |
| ( define_ring ) |
( define_ring ) |
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| (array a; array b;) |
(array a; array b;) |
| $b : [syzygy gb tmat input]; gb = tmat * input $ |
$b : [syzygy gb tmat input]; gb = tmat * input $ |
| $Example 1: [ [( (x Dx)^2 + (y Dy)^2 -1) ( x y Dx Dy -1)] (x,y) $ |
$Example 1: [ [( (x Dx)^2 + (y Dy)^2 -1) ( x y Dx Dy -1)] (x,y) $ |
| $ [ [ (Dx) 1 (Dy) 1] ] ] ecart.syz /ff set $ |
$ [ [ (Dx) 1 (Dy) 1] [(x) -1 (y) -1 (Dx) 1 (Dy) 1]] ] ecart.syz /ff set $ |
| $ ff 0 get ff 3 get mul pmat $ |
$ ff 0 get ff 3 get mul pmat $ |
| $ ff 2 get ff 3 get mul [ff 1 get ] transpose sub pmat ; $ |
$ ff 2 get ff 3 get mul [ff 1 get ] transpose sub pmat ; $ |
| ( ) |
( ) |
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(To set the current ring to the ring in which ff belongs ) |
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( ff getRing ring_def ) |
| $Example 2: [[ [(x^2) (y+x)] [(x+y) (y^3)] [(2 x^2+x y) (y+x+x y^3)]] (x,y) $ |
$Example 2: [[ [(x^2) (y+x)] [(x+y) (y^3)] [(2 x^2+x y) (y+x+x y^3)]] (x,y) $ |
| $ [ [ (x) -1 (y) -1] ] [[0 1] [-3 1] ] ] ecart.syz pmat ; $ |
$ [ [(Dx) 1 (Dy) 1] [ (x) -1 (y) -1] ] [[0 1] [-3 1] ] ] ecart.syz pmat ; $ |
| ( ) |
( ) |
| (cf. ecart.gb) |
(cf. ecart.gb) |
| ( /ecart.autoHomogenize 0 def ) |
( /ecart.autoHomogenize 0 def ) |
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| %%BUG: case of v is integer |
%%BUG: case of v is integer |
| v ecart.checkOrder |
v ecart.checkOrder |
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| ecart.begin |
ecartd.begin |
| [(EcartAutomaticHomogenization) 1] system_variable |
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| ecart.gb.verbose { (gb.options = ) messagen gb.options message } { } ifelse |
ecart.gb.verbose { (gb.options = ) messagen gb.options message } { } ifelse |
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| ifelse |
ifelse |
| } ifelse |
} ifelse |
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| ecart.end |
ecartd.end |
| [(EcartAutomaticHomogenization) 0] system_variable |
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| %% |
%% |
| env1 restoreOptions %% degreeShift changes "grade" |
env1 restoreOptions %% degreeShift changes "grade" |
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| /i set |
/i set |
| vv i get . /tt set |
vv i get . /tt set |
| tt (1). add init (1). eq { } |
tt (1). add init (1). eq { } |
| { [vv i get ( is larger than 1) vv i get] cat error} ifelse |
{ [vv i get ( is larger than 1 ) ] cat error} ifelse |
| } for |
} for |
| /arg1 1 def |
/arg1 1 def |
| ] pop |
] pop |
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