Annotation of OpenXM/src/k097/lib/minimal/example-ja.tex, Revision 1.3
1.3 ! takayama 1: % $OpenXM: OpenXM/src/k097/lib/minimal/example-ja.tex,v 1.2 2000/08/02 05:14:30 takayama Exp $
1.1 takayama 2: \documentclass[12pt]{jarticle}
3: \newtheorem{example}{Example}
4: \def\pd#1{ \partial_{#1} }
5: %% [2] should be replaced by \cite{....}
6:
7: \begin{document}
8: \section{�$BNc�(B}
9: �$B2f!9$,�(B $(u,v)$-�$B6K>.<+M3J,2r$N9=@.$K6=L#$r$b$C$?F05!$N�(B
10: �$B0l$D$O�(B, $D$ �$B2C72�(B $M$ �$B$N@)8B%3%[%b%m%8$N7W;;$N8zN(2=$G$"$k�(B.
11: [2] �$B$G$O�(B, $M$ �$B$N�(B Schreyer resolution �$B$,�(B $(-{\bf 1},{\bf 1})$
12: �$B$KE,9g$7$?�(B $M$ �$B$N<+M3J,2r$G$"$k$3$H$r>ZL@$7�(B,
13: �$B$3$l$rMQ$$$?@)8B%3%[%b%m%8$N7W;;K!$rM?$($?�(B.
14: �$B$3$NJ}K!$rE,MQ$9$k$K$O�(B
15: $(-w,w)$ �$B$KE,9g$7$?�(B $M$ �$B$N<+M3J,2r$J$i$J$s$G$b$h$/�(B,
16: Schreyer resolution �$B$r$H$kI,A3@-$O$J$$�(B.
17: [2] �$B$NJ}K!$G$O�(B, 1 �$BE@$X$N@)8B$r7W;;$9$k$N$K<!85�(B
18: $$O\left( (\mbox{ �$B<+M3J,2r$N�(B betti �$B?t�(B}) \times
19: \left(\mbox{$b$�$B4X?t$N:GBg@0?t:,�(B}\right)^n\right)$$
20: �$B$N%Y%/%H%k6u4V$NJ#BN$N�(B ${\rm Ker}/{\rm Im}$ �$B$r�(B
21: �$B7W;;$9$kI,MW$,@8$8$k�(B.
22: ( �$BItJ,B?MMBN$X$N@)8B$K$O�(B $D_m$, $(m < n)$ �$B<+M32C72$NJ#BN�(B
23: �$B$N%3%[%b%m%8$r7W;;$9$kI,MW$,$"$k�(B.)
24: �$B$7$?$,$C$F�(B, betti �$B?t$,Bg$-$/$J$k$H�(B, �$B7W;;$9$Y$-�(B �$B%Y%/%H%k6u4V$N<!85$,�(B
25: �$BBg$-$/$J$j�(B, �$B%a%b%jITB-$r$^$M$$$F$$$?�(B.
26: $(-w,w)$-�$B6K>.<+M3J,2r$N�(B betti �$B?t$O�(B Schreyer resolution �$B$N�(B betti �$B?t$K�(B
27: �$BHf3S$7$F$+$J$j>.$5$/$$$^$^$G@)8B$,7W;;$G$-$J$+$C$?Nc$b7W;;$G$-$k$h$&$K�(B
28: �$B$J$C$?�(B.
29:
30: Schreyer resolution �$B$N�(B betti �$B?t$H�(B $(-w,w)$-�$B6K>.<+M3J,2r$N�(B betti �$B?t$r�(B
31: �$B$$$/$D$+$NNc$K$D$$$FHf3S$7$F$_$h$&�(B.
32:
33: �$BHf3S$NA0$K$$$/$D$+5-9f$HM=HwCN<1$rF3F~$9$k�(B.
34: \begin{enumerate}
35: \item Schreyer resolution �$B$N�(B betti �$B?t$O�(B $(-w,w)$ �$B$@$1$G$J$/�(B
36: tie-breaking order �$B$K$b0MB8$9$k�(B.
37: �$B0J2<�(B tie-breaking order �$B$H$7$F�(B, graded reverse lexicographic order
38: �$B$rMQ$$$k�(B.
39: \item �$BB?9`<0�(B $f$ �$B$N�(B $b$-�$B4X?t$N:G>.@0?t:,$r�(B $-r$ �$B$H$9$k$H$-�(B
40: ${\rm Ann}(D f^{-1})$ �$B$G�(B
41: $1/f^r$ �$B$rNm2=$9$k�(B $D$ �$B$N%$%G%"%k$N$"$k@8@.85$N=89g$r$"$i$o$9�(B.
1.2 takayama 42: �$B2<$N<BNc$N>l9g$G$O4X?t�(B {\tt Sannfs(f,v)} �$B$N=PNO$r$"$i$o$9�(B.
1.1 takayama 43: \item $F(G)$ �$B$G�(B $G$ �$B$N�(B formal Laplace �$BJQ49$r$"$i$o$9�(B.
44: \item $F^h(G)$ �$B$G�(B $G$ �$B$N�(B formal Laplace �$BJQ49$r�(B homogenize �$B$7$?$b$N$r$"$i$o$9�(B.
45: \item Grothendieck �$B$NHf3SDjM}$K$h$l$P�(B
46: $I = F({\rm Ann} D f^{-1})$ �$B$H$*$/$H$-�(B $D/I$ �$B$N86E@$X$N@)8B%3%[%b%m%8�(B
47: �$B$,6u4V�(B $ {\bf C}^n \setminus V(f)$ �$B$N�(B ${\bf C}$-�$B78?t%3%[%b%m%872$K0lCW$9$k�(B.
48: ( "An algorithm for de Rham cohomology groups of the
49: complement of an affine variety via D-module computation",
50: Journal of pure and applied algebra, 139 (1999), 201--233. �$B$r;2>H�(B)
51: \end{enumerate}
52:
1.3 ! takayama 53: \begin{example} \rm \label{example:cusp}
1.1 takayama 54: %Prog: minimal-test.k test18()
55: $I = F^h\left[{\rm Ann}\left( D \frac{1}{x^3-y^2} \right) \right]$
56: �$B$N>l9g�(B.
57: �$B%$%G%"%k�(B $I$ �$B$O�(B
58: $$ -2x\pd{x}-3y\pd{y}+h^2 , -3y\pd{x}^2+2x\pd{y}h $$
59: �$B$G@8@.$5$l$k�(B.
60:
61: \begin{tabular}{|l|l|}
62: \hline
63: Resolution type & Betti numbers \\ \hline
1.2 takayama 64: Schreyer & 1, 4, 4, 1 \\ \hline
65: $(-{\bf 1},{\bf 1})$-minimal & 1, 2, 1 \\ \hline
66: minimal & 1, 2, 1 \\
1.1 takayama 67: \hline
68: \end{tabular}
69:
70: \noindent
71: $(-{\bf 1},{\bf 1})$-minimal resolution
72: {\footnotesize \begin{verbatim}
73: [
74: [
75: [ -2*x*Dx-3*y*Dy+h^2 ]
76: [ -3*y*Dx^2+2*x*Dy*h ]
77: ]
78: [
79: [ -3*y*Dx^2+2*x*Dy*h , 2*x*Dx+3*y*Dy ]
80: ]
81: ]
82: Degree shifts
83: [ [ 0 ] , [ 0 , 1 ] ]
84: \end{verbatim}}
85: Schreyer Resolution %%Prog: a=test18(); sm1_pmat(a[3]);
86: {\footnotesize \begin{verbatim}
87: [
88: [
89: [ -2*x*Dx-3*y*Dy+h^2 ]
90: [ -3*y*Dx^2+2*x*Dy*h ]
91: [ 9*y^2*Dx*Dy+3*y*Dx*h^2+4*x^2*Dy*h ]
92: [ 27*y^3*Dy^2+27*y^2*Dy*h^2-3*y*h^4-8*x^3*Dy*h ]
93: ]
94: [
95: [ 9*y^2*Dy+3*y*h^2 , 0 , 2*x , 1 ]
96: [ -4*x^2*Dy*h , 0 , -3*y*Dy+4*h^2 , Dx ]
97: [ 2*x*Dy*h , 3*y*Dy-2*h^2 , Dx , 0 ]
98: [ 3*y*Dx , -2*x , 1 , 0 ]
99: ]
100: [
101: [ -Dx , 1 , 2*x , 3*y*Dy-2*h^2 ]
102: ]
103: ]
104: \end{verbatim}}
105: \end{example}
106:
107: \begin{example} \rm
108: %Prog: minimal-test.k test17b()
109: $I = F^h\left[{\rm Ann}\left( D \frac{1}{x^3-y^2z^2} \right) \right]$
110: �$B$N>l9g�(B.
111:
112: \begin{tabular}{|l|l|}
113: \hline
114: Resolution type & Betti numbers \\ \hline
1.2 takayama 115: Schreyer & 1, 8, 16, 11, 2 \\ \hline
116: $(-{\bf 1},{\bf 1})$-minimal & 1, 4, 5, 2 \\ \hline
117: minimal & 1, 4, 5, 2 \\
1.1 takayama 118: \hline
119: \end{tabular}
120:
121: \noindent
122: $(-{\bf 1},{\bf 1})$-minimal resolution
123: {\footnotesize \begin{verbatim}
124: [
125: [
126: [ y*Dy-z*Dz ]
127: [ -2*x*Dx-3*z*Dz+h^2 ]
128: [ 2*x*Dy*Dz^2-3*y*Dx^2*h ]
129: [ 2*x*Dy^2*Dz-3*z*Dx^2*h ]
130: ]
131: [
132: [ 0 , 2*x*Dy^2*Dz-3*z*Dx^2*h , 0 , 2*x*Dx+3*z*Dz ]
133: [ 2*x*Dx+3*z*Dz-h^2 , y*Dy-z*Dz , 0 , 0 ]
134: [ 3*Dx^2*h , 0 , Dy , -Dz ]
135: [ 6*x*Dy*Dz^2-9*y*Dx^2*h , -2*x*Dy*Dz^2+3*y*Dx^2*h , -2*x*Dx-3*y*Dy , 0 ]
136: [ 2*x*Dy*Dz , 0 , z , -y ]
137: ]
138: [
139: [ y , -2*x*Dy*Dz , 3*y*z , z , 2*x*Dx ]
140: [ Dz , -3*Dx^2*h , 2*x*Dx+3*y*Dy+3*z*Dz+6*h^2 , Dy , -3*Dy*Dz ]
141: ]
142: ]
143: Degree shifts
144: [ [ 0 ] , [ 0 , 0 , 2 , 2 ] , [ 2 , 0 , 3 , 2 , 1 ] ]
145: \end{verbatim}}
146: \end{example}
147:
148: \begin{example} \rm
149: %Prog: minimal-test.k test22();
150: $I = F^h\left[{\rm Ann}\left( D \frac{1}{x^3+y^3+z^3} \right) \right]$
151: �$B$N>l9g�(B.
152:
153: %% Uli Walther �$B$N�(B �$BO@J8�(B (MEGA 2000) �$B$NNc$H�(B betti �$B?t$rHf3S$;$h�(B.
154: \begin{tabular}{|l|l|}
155: \hline
156: Resolution type & Betti numbers \\ \hline
1.2 takayama 157: Schreyer & 1, 12, 44, 75, 70, 39, 13, 2 \\ \hline
158: $(-1,-2,-3,1,2,3)$-minimal & 1, 4, 5, 2 \\ \hline
159: minimal & 1, 4, 5, 2 \\
1.1 takayama 160: \hline
161: \end{tabular}
162:
163: \noindent
1.2 takayama 164: $(-1,-2,-3,1,2,3)$-minimal resolution
1.1 takayama 165: {\footnotesize \begin{verbatim}
1.2 takayama 166: [
167: [
168: [ x*Dx+y*Dy+z*Dz-3*h^2 ]
169: [ y*Dz^2-z*Dy^2 ]
170: [ x*Dz^2-z*Dx^2 ]
171: [ x*Dy^2-y*Dx^2 ]
172: ]
173: [
174: [ 0 , -x , y , -z ]
175: [ -x*Dz^2+z*Dx^2 , x*Dy , x*Dx+z*Dz-3*h^2 , z*Dy ]
176: [ -x*Dy^2+y*Dx^2 , -x*Dz , y*Dz , x*Dx+y*Dy-3*h^2 ]
177: [ -y*Dz^2+z*Dy^2 , x*Dx+y*Dy+z*Dz-2*h^2 , 0 , 0 ]
178: [ 0 , Dx^2 , -Dy^2 , Dz^2 ]
179: ]
180: [
181: [ -x*Dx+3*h^2 , y , -z , -x , 0 ]
182: [ -Dz^3-Dy^3 , -Dy^2 , Dz^2 , Dx^2 , -x*Dx-y*Dy-z*Dz ]
183: ]
184: ]
185: Degree shifts
186: [ [ 0 ] , [ 0 , 4 , 5 , 3 ] , [ 3 , 5 , 6 , 4 , 9 ] ]
1.1 takayama 187: \end{verbatim}}
188: \end{example}
189:
190:
191: \begin{example} \rm
192: %Prog: minimal-test.k test21();
193: $I = F^h\left[{\rm Ann}\left( D \frac{1}{x^3-y^2z^2+y^2+z^2} \right) \right]$
194: �$B$N>l9g�(B.
195:
196: \begin{tabular}{|l|l|}
197: \hline
198: Resolution type & Betti numbers \\ \hline
1.2 takayama 199: Schreyer & 1, 13, 43, 50, 21, 2 \\ \hline
200: $(-{\bf 1},{\bf 1})$-minimal & 1, 7, 10, 4 \\ \hline
201: minimal & 1, 7, 10, 4 \\
1.1 takayama 202: \hline
203: \end{tabular}
204:
205: \noindent
1.2 takayama 206: $f=x^3-y^2z^2+y^2+z^2$ �$B$H$*$$$?>l9g�(B,
207: �$B6u4V�(B ${\bf C}^3 \setminus V(f)$ �$B$N�(B
208: �$B%3%[%b%m%872$N<!85$O�(B
209: ${\rm dim}\, H^i = 1$, $(i=0, 1)$,
210: ${\rm dim}\, H^i = 0$, $(i=2, 3)$,
211: �$B$H$J$k�(B.
212: �$B$3$N>l9g�(B $D/I$ �$B$N�(B
213: $b$-�$B4X?t$N:GBg@0?t:,$O�(B $2$ �$B$H$J$j�(B,
214: �$B%3%[%b%m%8$r7W;;$9$k$?$a$K�(B
215: �$B9M$($k@~7A6u4V$NJ#BN$N<!85$O�(B, $10, 12, 9, 4$ �$B$G$"$k�(B. %%Prog: Srestall.sm1
216: �$B0lJ}�(B Schreyer resolution �$B$+$i%9%?!<%H$7$F�(B,
1.1 takayama 217: �$B@~7A6u4V$NJ#BN$r9M$($k$H�(B, �$B$=$N<!85$O�(B
1.2 takayama 218: 130, 1078, 1667, 749, 40 �$B$H$J$k�(B. %%Prog: test21b()
1.1 takayama 219: \end{example}
220:
221: \begin{example} \rm
222: %Prog: minimal-test.k test20()
1.2 takayama 223: $I = D\cdot\{ x_1\pd{1}+2x_2\pd{2}+3x_3\pd{3} ,
224: \pd{1}^2-\pd{2}h,
225: -\pd{1}\pd{2}+\pd{3}h,
1.1 takayama 226: \pd{2}^2-\pd{1}\pd{3} \}
227: $ �$B$N>l9g�(B.
228: �$B$3$l$O�(B $A=(1,2,3)$, $\beta=0$ �$B$KIU?o$9$k�(B GKZ �$BD64v2?7O$N�(B
229: homogenization.
230:
231: \begin{tabular}{|l|l|}
232: \hline
233: Resolution type & Betti numbers \\ \hline
1.2 takayama 234: Schreyer & 1, 10, 25, 23, 8, 1 \\ \hline
235: $(-{\bf 1},{\bf 1})$-minimal & 1, 4, 5, 2 \\ \hline
236: minimal & 1, 4, 5, 2 \\
1.1 takayama 237: \hline
238: \end{tabular}
239:
240: \noindent
241: $(-{\bf 1},{\bf 1})$-minimal resolution
242: {\footnotesize \begin{verbatim}
243: [
244: [
245: [ x1*Dx1+2*x2*Dx2+3*x3*Dx3 ]
246: [ Dx1^2-Dx2*h ]
247: [ -Dx1*Dx2+Dx3*h ]
248: [ Dx2^2-Dx1*Dx3 ]
249: ]
250: [
251: [ Dx1*Dx2-Dx3*h , -x1*Dx2 , 2*x2*Dx2+3*x3*Dx3+3*h^2 , -x1*h ]
252: [ Dx1^2-Dx2*h , -x1*Dx1-3*x3*Dx3-2*h^2 , 2*x2*Dx1 , 2*x2*h ]
253: [ Dx2^2-Dx1*Dx3 , x1*Dx3 , x1*Dx2 , -2*x2*Dx2-3*x3*Dx3-4*h^2 ]
254: [ 0 , Dx3 , Dx2 , Dx1 ]
255: [ 0 , -Dx2 , -Dx1 , -h ]
256: ]
257: [
258: [ Dx2 , -Dx3 , -Dx1 , -2*x2*Dx2-3*x3*Dx3-4*h^2 , -x1*Dx2-2*x2*Dx3 ]
259: [ -Dx1 , Dx2 , h , -x1*h , -3*x3*Dx3-h^2 ]
260: ]
261: ]
262: Degree shifts
263: [ [ 0 ] , [ 0 , 2 , 2 , 2 ] , [ 2 , 2 , 2 , 3 , 3 ] ]
264: \end{verbatim}}
1.3 ! takayama 265: %%Prog:test23() of minimal-test.k
! 266: �$B$3$N6K>.<+M3J,2r$O<B$O�(B �$B9TNs�(B $(1,2,3)$ �$B$G$-$^$k�(B affine toric ideal
! 267: �$B$N6K>.<+M3J,2r$N�(B Koszul complex �$B$K$J$C$F$k�(B.
! 268: Gel'fand, Kapranov, Zelevinsky �$B$K$h$C$FF3F~$5$l$?�(B $D/I$
! 269: �$B$N�(B resolution �$B$r<+A3$K1dD9$7$?<!$N�(B 2 �$B=EJ#BN$r9M$($h$&�(B.
! 270: $$
! 271: \begin{array}{ccccccccc}
! 272: 0 & \longrightarrow & D^2 & \stackrel{d^1}{\longrightarrow}
! 273: & D^3 & \stackrel{d^2}{\longrightarrow}
! 274: & D & \longrightarrow & 0 \\
! 275: & & u^1 \downarrow &
! 276: & u^2 \downarrow &
! 277: & u^3 \downarrow & \\
! 278: 0 & \longrightarrow & D^2 & \stackrel{d^1}{\longrightarrow}
! 279: & D^3 & \stackrel{d^2}{\longrightarrow}
! 280: & D & \longrightarrow & 0
! 281: \end{array}
! 282: $$
! 283: �$B$3$3$G$O�(B, (�$B8m2r$b$J$$$H;W$&$N$G�(B) $D$ �$B$GF1<!2=%o%$%kBe?t�(B,
! 284: $d^i$ �$B$G�(B affine toric ideal �$B$NF1<!2=$NB?9`<04D$G$N6K>.<+M3J,2r�(B
! 285: $$ d^2 = \pmatrix{ \pd{1}^2 - \pd{2}^2 h \cr
! 286: -\pd{1} \pd{2} + \pd{3} h \cr
! 287: \pd{2}^2 - \pd{1} \pd{3} \cr }, \
! 288: d^1 = \pmatrix{ -\pd{2} & -\pd{1} & -h \cr
! 289: \pd{3} & \pd{2} & \pd{1} \cr }
! 290: $$
! 291: �$B$r$"$i$o$9$b$N$H$9$k�(B.
! 292: �$B$^$?�(B $\ell = x_1 \pd{1} + 2 x_2 \pd{2} + 3 x_3 \pd{3}$ �$B$H$*$/$H$-�(B $u^i$ �$B$r�(B
! 293: �$B<!$N$h$&$K$-$a$k�(B.
! 294: $$ u^1=\pmatrix{ \ell + 4 h^2 & 0 \cr
! 295: 0 & \ell+5 h^2 \cr}, \quad
! 296: u^2=\pmatrix{\ell+2 h^2 & 0 & 0 \cr
! 297: 0 & \ell + 3 h^2 & 0 \cr
! 298: 0 & 0 & \ell+ 4 h^2 \cr}, \quad
! 299: u^3 = \pmatrix{ \ell \cr}.
! 300: $$
! 301:
! 302: �$B$3$N$H$-IU?o$9$k�(B 1 �$B=EJ#BN$O�(B
! 303: $$L^1 \ni f \mapsto (-d^1(f), u^1(f)) \in L^2 \oplus L^1, $$
! 304: $$ L^2\oplus L^1 \ni (f,g)\mapsto (-d^2(f), u^2(f)+d^1(g)) \in L^3\oplus L^2,
! 305: $$
! 306: $$
! 307: L^3\oplus L^2 \ni (f,g)\mapsto u^3(f)+d^2(g) \in L^3.
! 308: $$
! 309: �$B$G$"$?$($i$l$k�(B.
! 310: �$B$3$3$G�(B $L^1 = D^2$, $L^2 = D^3$, $L^3 = D$ �$B$G$"$k�(B.
! 311: �$B$3$N�(B 1 �$B=EJ#BN$N6qBN7A$O0J2<$N$H$&$j�(B.
! 312: \footnotesize{
! 313: \begin{verbatim}
! 314: [
! 315: [
! 316: [ x1*Dx1+2*x2*Dx2+3*x3*Dx3 ]
! 317: [ Dx1^2-Dx2*h ]
! 318: [ -Dx1*Dx2+Dx3*h ]
! 319: [ Dx2^2-Dx1*Dx3 ]
! 320: ]
! 321: [
! 322: [ -Dx1^2+Dx2*h , x1*Dx1+2*x2*Dx2+3*x3*Dx3+2*h^2 , 0 , 0 ]
! 323: [ Dx1*Dx2-Dx3*h , 0 , x1*Dx1+2*x2*Dx2+3*x3*Dx3+3*h^2 , 0 ]
! 324: [ -Dx2^2+Dx1*Dx3 , 0 , 0 , x1*Dx1+2*x2*Dx2+3*x3*Dx3+4*h^2 ]
! 325: [ 0 , -Dx2 , -Dx1 , -h ]
! 326: [ 0 , Dx3 , Dx2 , Dx1 ]
! 327: ]
! 328: [
! 329: [ Dx2 , Dx1 , h , x1*Dx1+2*x2*Dx2+3*x3*Dx3+4*h^2 , 0 ]
! 330: [ -Dx3 , -Dx2 , -Dx1 , 0 , x1*Dx1+2*x2*Dx2+3*x3*Dx3+5*h^2 ]
! 331: ]
! 332: ]
! 333: \end{verbatim}
! 334: }
1.1 takayama 335: \end{example}
336:
337:
338:
339:
1.3 ! takayama 340: \section{�$B<BAu�(B}
! 341: �$B$3$3$G$O�(B
! 342: \begin{verbatim}
! 343: /* OpenXM: OpenXM/src/k097/lib/minimal/minimal.k,v 1.25
! 344: 2000/08/02 05:14:31 takayama Exp */
! 345: \end{verbatim}
! 346: �$BHG$N�(B {\tt minimal.k} �$B$K=`5r$7$F<BAu$N35N,$r2r@b$9$k�(B.
! 347:
! 348: �$B<BAu$N@bL@$N$?$a$NNc$H$7$F%$%G%"%k�(B
! 349: $$ I = D \cdot \{ -2x\pd{x}-3y\pd{y}+h^2, -3y\pd{x}^2+2x\pd{y}h \} $$
! 350: �$B$N�(B $(u,v) = (-1,-1,1,1)$-�$B6K>.J,2r$N9=@.�(B
! 351: �$B$r9M$($h$&�(B.
! 352: %%Prog: minimal-note-ja.txt 6/9 (Fri) �$B$*$h$S0J8e$N�(B bug fix �$B$N5-O?$r;2>H�(B.
! 353: %%�$BNc$H$7$F�(B, �$B%$%G%"%k�(B
! 354: %%$$ I = D \cdot \{ x^2 + y^2, x y \} $$
! 355: %%�$B$N�(B $(u,v) = (-1,-1,1,1)$-�$B6K>.J,2r$N9=@.�(B
! 356: %%�$B$r9M$($h$&�(B.
! 357: %%(�$B$3$N>l9g$OB?9`<04D$NF1<!<0$G@8@.$5$l$k$N$G�(B, �$BB?9`<04D$G$N�(B
! 358: %% �$B6K>.<+M3J,2r$N7W;;$HF1$8$3$H$K$J$k�(B.)
! 359: �$B$3$N>l9g�(B,
! 360: $I$ �$B$N%0%l%V%J4pDl�(B $G$ �$B$O�(B
! 361: {\footnotesize
! 362: \begin{verbatim}
! 363: [
! 364: [ -2*x*Dx-3*y*Dy+h^2 ]
! 365: [ -3*y*Dx^2+2*x*Dy*h ]
! 366: [ 9*y^2*Dx*Dy+3*y*Dx*h^2+4*x^2*Dy*h ]
! 367: [ 27*y^3*Dy^2+27*y^2*Dy*h^2-3*y*h^4-8*x^3*Dy*h ]
! 368: ]
! 369: \end{verbatim}
! 370: } \noindent
! 371: �$B$H$J$C$F$*$j�(B,
! 372: Schreyer resolution �$B$O�(B
! 373: {\footnotesize
! 374: \begin{verbatim}
! 375: [
! 376: [
! 377: [ -2*x*Dx-3*y*Dy+h^2 ]
! 378: [ -3*y*Dx^2+2*x*Dy*h ]
! 379: [ 9*y^2*Dx*Dy+3*y*Dx*h^2+4*x^2*Dy*h ]
! 380: [ 27*y^3*Dy^2+27*y^2*Dy*h^2-3*y*h^4-8*x^3*Dy*h ]
! 381: ]
! 382: [
! 383: [ 9*y^2*Dy+3*y*h^2 , 0 , 2*x , 1 ]
! 384: [ -4*x^2*Dy*h , 0 , -3*y*Dy+4*h^2 , Dx ]
! 385: [ 2*x*Dy*h , 3*y*Dy-2*h^2 , Dx , 0 ]
! 386: [ 3*y*Dx , -2*x , 1 , 0 ]
! 387: ]
! 388: [
! 389: [ -Dx , 1 , 2*x , 3*y*Dy-2*h^2 ]
! 390: ]
! 391: ]
! 392: \end{verbatim}
! 393: } \noindent
! 394: �$B$G$"$k�(B. $1$ �$B$,$?$/$5$s�(B Schreyer resolution �$B$NCf$K$O$"$k$3$H$K�(B
! 395: �$BCm0U�(B. $1$ �$B$O6K>.<+M3J,2r$K$OI,MW$J$$85$G$"$k$3$H$r0UL#$9$k�(B.
! 396: �$B6K>.<+M3J,2r$O�(B, �$BNc�(B \ref{example:cusp} �$B$K6qBN7A$r=q$$$F$*$$$?�(B.
! 397:
! 398: \medbreak
! 399:
! 400:
! 401: �$B$3$N<BAu$G$O6K>.<+M3J,2r$r�(B LaScala �$B$N%"%k%4%j%:%`$r$b$H$K$7$F�(B
! 402: �$B9=@.$9$k�(B (LaScala and Stillman [??] �$B$*$h$S?tM}2J3X$N5-;v�(B ??? �$B$r;2>H�(B).
! 403:
! 404: �$B$3$N%"%k%4%j%:%`$O4{CN$H$7$F�(B, �$B0c$$$N$_$r@bL@$7$h$&�(B.
! 405: LaScala �$B$N%"%k%4%j%:%`$O�(B,
! 406: reduction �$B$7$?$H$-$K�(B $0$ �$B$K$J$C$?>l9g�(B, �$B$=$N�(B reduction �$B$KIU?o$7$?�(B
! 407: syzygy �$B$r�(B �$B6K>.<+M3J,2r$N85$H$7�(B,
! 408: reduction �$B$7$?$H$-$K�(B $0$ �$B$K$J$i$J$+$C$?>l9g�(B, �$B$=$N85$r�(B
! 409: �$B%0%l%V%J4pDl$N85$H$7$F2C$(�(B, �$BIU?o$7$?�(B syzygy �$B$O6K>.<+M3J,2r$G$OM>7W$J$b$N$H�(B
! 410: �$B$_$J$9�(B.
! 411: �$B$o$l$o$l$O�(B $(u,v)$-�$B6K>.$J<+M3J,2r$r$b$H$a$?$$�(B.
! 412: �$B$=$3$G>e$N<jB3$-$r<!$N$h$&$KJQ$($k�(B.
! 413: \begin{center}
! 414: \begin{minipage}{10cm}
! 415: Reduction �$B$7$?$H$-$K�(B modulo $(u,v)$-�$B%U%#%k%?!<$G�(B $0$ �$B$K$J$C$?>l9g�(B,
! 416: �$B$=$N�(B reduction �$B$KIU?o$7$?�(B syzygy �$B$r�(B �$B6K>.<+M3J,2r$N85$H$7�(B, �$B$5$i$K�(B
! 417: �$B$=$N85$,�(B $0$ �$B$G$J$1$l$P%0%l%V%J4pDl$K2C$($k�(B.
! 418: reduction �$B$7$?$H$-$K�(B modulo $(u,v)$-�$B%U%#%k%?!<$G�(B $0$ �$B$K$J$i$J$+$C$?>l9g�(B,
! 419: �$B$=$N85$r%0%l%V%J4pDl$N85$H$7$F2C$(�(B,
! 420: �$BIU?o$7$?�(B syzygy �$B$O6K>.<+M3J,2r$G$OM>7W$J$b$N$H$_$J$9�(B.
! 421: \end{minipage}
! 422: \end{center}
! 423:
! 424: �$B$A$J$_$K�(B,
1.1 takayama 425: $(-w,w)$-�$B6K>.<+M3J,2r$H�(B �$B6K>.<+M3J,2r$,$3$H$J$kNc$r$5$,$7$F$$$k$,�(B
426: �$B$3$l$O$^$@8+$D$+$C$F$$$J$$�(B.
1.3 ! takayama 427: �$B$A$g$C$HIT;W5D$G$"$k�(B.
! 428:
! 429: \bigbreak
! 430:
! 431: {\tt minimal.k} �$B$N%=!<%9%3!<%I$G$O$3$NItJ,$O<!$N$h$&$K$J$C$F$$$k�(B.
! 432: {\footnotesize
! 433: \begin{verbatim}
! 434: def SlaScala(g,opt) {
! 435: ...
! 436: ...
! 437: f = SpairAndReduction(skel,level,i,freeRes,tower,ww);
! 438: if (f[0] != Poly("0")) {
! 439: place = f[3];
! 440: if (Sordinary) {
! 441: redundantTable[level-1,place] = redundant_seq;
! 442: redundant_seq++;
! 443: }else{
! 444: if (f[4] > f[5]) { (�$B$$�(B)
! 445: /* Zero in the gr-module */
! 446: Print("v-degree of [org,remainder] = ");
! 447: Println([f[4],f[5]]);
! 448: Print("[level,i] = "); Println([level,i]);
! 449: redundantTable[level-1,place] = 0;
! 450: }else{ (�$B$m�(B)
! 451: redundantTable[level-1,place] = redundant_seq;
! 452: redundant_seq++;
! 453: }
! 454: }
! 455: redundantTable_ordinary[level-1,place]
! 456: =redundant_seq_ordinary;
! 457: ...
! 458: ...
! 459: }
! 460: \end{verbatim}
! 461: }
! 462:
! 463: �$B>/!9D9$/$J$k$,�(B, �$B$3$NItJ,$K$"$i$o$l$kJQ?t$N@bL@$r$7$h$&�(B.
! 464:
! 465: LaScala �$B$N%"%k%4%j%:%`$G$O�(B, �$B:G=i$K7W;;$9$Y$-�(B S-pair �$B$N7W;;<j=g�(B,
! 466: �$B$*$h$S�(B Schreyer frame �$B$r:n@.$9$k�(B.
! 467: Schreyer frame �$B$O�(B Schreyer resolution �$B$N�(B initial �$B$G$"$k�(B.
! 468: �$B$3$l$i$O$"$i$+$8$a�(B
! 469: {\tt SresolutionFrameWithTower(g,opt);}
! 470: �$B$G7W;;$5$l$F�(B, {\tt tower} �$B$*$h$S�(B {\tt skel} �$B$K3JG<$5$l$F$$$k�(B.
! 471: �$B$3$l$i$NJQ?t$NCM$O�(B, �$B4X?t�(B {\tt Sminimal()} �$B$NLa$jCM$H$7$F�(B
! 472: �$B8+$k$3$H$,$G$-$k�(B.
! 473: �$B4X?t�(B {\tt Sminimal()} �$B$NLa$jCM$,JQ?t�(B $a$ �$B$K3JG<$5$l$F$$$k$H$9$k$H�(B,
! 474: {\tt a[0]} �$B$,6K>.<+M3J,2r�(B
! 475: {\tt a[3]} �$B$,�(B Schreyer �$B<+M3J,2r�(B(�$B$H$/$K�(B {\tt a[3,0]} �$B$,�(B
! 476: $I$ �$B$N%0%l%V%J4pDl�(B),
! 477: {\tt a[4]} �$B$,�(B,
! 478: �$B4X?t�(B {\tt SlaScala()} �$B$N�(B
! 479: �$BJQ?t�(B {\tt [rf[0], tower, skel, rf[3]]} �$B$NCM$G$"$k�(B.
! 480: �$B$7$?$,$C$F�(B, {\tt tower} �$B$O�(B {\tt a[4,1]} �$B$K3JG<$5$l$F$$$k�(B.
! 481: $I$ �$B$N>l9g$N�(B {\tt tower} �$B$O0J2<$N$H$&$j�(B.
! 482: {\footnotesize
! 483: \begin{verbatim}
! 484: In(25)=sm1_pmat(a[4,1]);
! 485: [
! 486: [ -2*x*Dx , -3*y*Dx^2 , -9*y^2*Dx*Dy , -27*y^3*Dy^2 ]
! 487: [ -9*y^2*Dy , -3*es^2*y*Dy , -3*es*y*Dy , -3*y*Dx ]
! 488: [ -Dx ]
! 489: ]
! 490: \end{verbatim}
! 491: } \noindent
! 492: �$B$3$3$G�(B ${\tt es}^i$ �$B$O%Y%/%H%k$N�(B �$BBh�(B $i$ �$B@.J,$G$"$k$3$H$r$7$a$7$F$$$k�(B.
! 493: �$B$?$H$($P�(B,
! 494: \verb# -3*es^2*y*Dy # �$B$O�(B
! 495: \verb# [0, 0, -3*y*Dy, 0] # �$B$r0UL#$9$k�(B.
! 496:
! 497: �$BJQ?t�(B
! 498: {\tt skel} �$B$K$O�(B
! 499: S-pair (sp) �$B$N7W;;<j=g$,$O$$$C$F$$$k�(B.
! 500: $I$ �$B$N>l9g$K$O0J2<$N$H$&$j�(B.
! 501: {\footnotesize
! 502: \begin{verbatim}
! 503: In(16)=sm1_pmat(a[4,2]);
! 504: [
! 505: [ ]
! 506: [
! 507: [
! 508: [ 0 , 2 ] G'[0] �$B$H�(B G'[2] �$B$N�(B sp �$B$r7W;;�(B (0)
! 509: [ -9*y^2*Dy , 2*x ]
! 510: ]
! 511: [
! 512: [ 2 , 3 ] G'[2] �$B$H�(B G'[3] �$B$N�(B sp �$B$r7W;;�(B (1)
! 513: [ -3*y*Dy , Dx ]
! 514: ]
! 515: [
! 516: [ 1 , 2 ] G'[1] �$B$H�(B G'[2] �$B$N�(B sp �$B$r7W;;�(B (2)
! 517: [ -3*y*Dy , Dx ]
! 518: ]
! 519: [
! 520: [ 0 , 1 ] G'[0] �$B$H�(B G'[1] �$B$N�(B sp �$B$r7W;;�(B (3)
! 521: [ -3*y*Dx , 2*x ]
! 522: ]
! 523: ]
! 524: [
! 525: [
! 526: [ 0 , 3 ] G''[0] �$B$H�(B G''[3] �$B$N�(B sp �$B$r7W;;�(B
! 527: [ -Dx , 3*y*Dy ]
! 528: ]
! 529: ]
! 530: [ ]
! 531: ]
! 532: \end{verbatim}
! 533: } \noindent
! 534: �$B$3$3$G�(B $G'$ �$B$O�(B Schreyer order �$B$GF@$i$l$?�(B $G$ �$B$N�(B syzygy �$B$N@8@.85�(B,
! 535: $G''$ �$B$O�(B Schreyer order �$B$GF@$i$l$?�(B $G'$ �$B$N�(B syzygy �$B$N@8@.85$r$"$i$o$9�(B.
! 536: �$B$?$H$($P>e$NNc$G$O�(B,
! 537: $G'[0]$ �$B$O�(B
! 538: $G[0]$ �$B$H�(B $G[2]$ �$B$N�(B sp �$B$N7W;;$K$h$jF@$i$l$?�(B syzygy,
! 539: $G'[1]$ �$B$O�(B
! 540: $G[2]$ �$B$H�(B $G[3]$ �$B$N�(B sp �$B$N7W;;$K$h$jF@$i$l$?�(B syzygy,
! 541: ...
! 542: �$B$r0UL#$9$k�(B.
! 543:
! 544: {\footnotesize
! 545: \begin{verbatim}
! 546: f = SpairAndReduction(skel,level,i,freeRes,tower,ww);
! 547: \end{verbatim}
! 548: } \noindent
! 549: �$B$G$O�(B {\tt skel[level,i]} �$B$K3JG<$5$l$?�(B
! 550: S-pair �$B$r7W;;$7$F�(B, {\tt freeRes[level-1]} �$B$G�(B reduction �$B$r$*$3$J$&�(B.
! 551: Reduction �$B$N$?$a$N�(B Schreyer order �$B$O�(B \\
! 552: {\tt StowerOf(tower,level-1)} �$B$rMQ$$$k�(B.
! 553: �$B$?$H$($P�(B, ${\tt [level,i] = [1,3]}$ �$B$N$H$-$K�(B
! 554: �$B4X?t�(B {\tt SpairAndReduction} �$B$G�(B
! 555: �$B$I$N$h$&$J7W;;$,$J$5$l$F$$$k$+�(B $I$ �$B$N>l9g$K$_$F$_$h$&�(B.
! 556:
! 557: {\tt SpairAndReduction} �$B$N<B9T;~�(B
! 558: �$B$K<!$N$h$&$J%a%C%;!<%8$,$G$F$/$k�(B.
! 559: {\footnotesize
! 560: \begin{verbatim}
! 561: reductionTable= [
! 562: [ 1 , 2 , 3 , 4 ]
! 563: [ 3 , 4 , 3 , 2 ]
! 564: [ 3 ]
! 565: ]
! 566: [ 0 , 0 ]
! 567: Processing [level,i]= [ 0 , 0 ] Strategy = 1
! 568: [ 0 , 1 ]
! 569: Processing [level,i]= [ 0 , 1 ] Strategy = 2
! 570: [ 1 , 3 ]
! 571: Processing [level,i]= [ 1 , 3 ] Strategy = 2
! 572: SpairAndReduction:
! 573: [ p and bases , [ [ 0 , 1 ] , [ -3*y*Dx , 2*x ] ] ,
! 574: [-2*x*Dx-3*y*Dy+h^2 , -3*y*Dx^2+2*x*Dy*h , %[null] , %[null] ] ]
! 575: [ level= , 1 ]
! 576: [ tower2= , [ [ ] ] ]
! 577: [ -3*y*Dx , 2*es*x ]
! 578: [gi, gj] = [ -2*x*Dx-3*y*Dy+h^2 , -3*y*Dx^2+2*x*Dy*h ]
! 579: 1
! 580: Reduce the element 9*y^2*Dx*Dy+3*y*Dx*h^2+4*x^2*Dy*h
! 581: by [ -2*x*Dx-3*y*Dy+h^2 , -3*y*Dx^2+2*x*Dy*h , %[null] , %[null] ]
! 582: result is [ 9*y^2*Dx*Dy+3*y*Dx*h^2+4*x^2*Dy*h , 1 , [ 0 , 0 , 0 , 0 ] ]
! 583: vdegree of the original = 0
! 584: vdegree of the remainder = 0
! 585: [ 9*y^2*Dx*Dy+3*y*Dx*h^2+4*x^2*Dy*h ,
! 586: [ -3*y*Dx , 2*x , 0 , 0 ] , 3 , 2 , 0 , 0 ]
! 587: \end{verbatim}
! 588: } \noindent
! 589: �$B:G=i$KI=<($5$l$k�(B {\tt reductionTable} �$B$N0UL#$O$"$H$G@bL@$9$k�(B.
! 590: �$B<!$N9T$KCmL\$7$h$&�(B. �$B$3$3$G$O�(B {\tt skel[0,4]} �$B$N�(B S-pair
! 591: �$B$r7W;;$7$F�(Breduction �$B$7$F$$$k�(B.
! 592: {\footnotesize
! 593: \begin{verbatim}
! 594: SpairAndReduction:
! 595: [ p and bases , [ [ 0 , 1 ] , [ -3*y*Dx , 2*x ] ] ,
! 596: [-2*x*Dx-3*y*Dy+h^2 , -3*y*Dx^2+2*x*Dy*h , %[null] , %[null] ] ]
! 597: \end{verbatim}
! 598: } \noindent
! 599: {\tt [0, 1]} �$B$O�(B $G'[0]$ �$B$H�(B $G'[1]$ �$B$N�(B sp �$B$r7W;;�(B
! 600: �$B$;$h$H$$$&0UL#$G$"$k�(B.
! 601: ${\tt level} = 0$ �$B$G4{$K$b$H$^$C$F$$$k�(B �$B%V%l%V%J4pDl$O�(B
! 602: $G[0]$ �$B$H�(B $G[1]$ �$B$N$_$G$"$j�(B,
! 603: �$B$=$l$i$O$=$l$>$l�(B,
! 604: \verb# -2*x*Dx-3*y*Dy+h^2 , -3*y*Dx^2+2*x*Dy*h #
! 605: �$B$G$"$k�(B.
! 606: {\tt SpairAndReduction} �$B$O�(B $G[0]$, $G[1]$ �$B$N$_$rMQ$$$F�(B,
! 607: S-pair \\
! 608: \verb# 9*y^2*Dx*Dy+3*y*Dx*h^2+4*x^2*Dy*h #
! 609: �$B$r�(B reduction �$B$9$k�(B.
! 610: �$B7k6I�(B reduction �$B$N7k2L$O�(B 0 �$B$G$O$J$/$F�(B, \\
! 611: \verb# 9*y^2*Dx*Dy+3*y*Dx*h^2+4*x^2*Dy*h #
! 612: �$B$H$J$k�(B.
! 613: LaScala �$B$N%"%k%4%j%:%`$N�(B 2 �$BG\$*F@%7%9%F%`$G�(B,
! 614: �$B$3$l$,?7$7$$%0%l%V%J4pDl$N85�(B {\tt G[place]} �$B$H$J$j�(B,
! 615: reduction �$B$N2aDx$h$j�(B syzygy �$B$bF@$i$l$k�(B.
! 616:
! 617: �$B$5$F�(B, $(u,v)$-�$B6K>.J,2r$r:n$k$K$O�(B, reduction �$B$7$?M>$j$,�(B
! 618: $(u,v)$-�$B%U%#%k%?!<$G�(B modulo �$B$7$F�(B $0$ �$B$+$I$&$+D4$Y$J$$$H$$$1$J$$�(B.
! 619: �$B$3$N$?$a�(B,
! 620: �$B4X?t�(B {\tt Sdegree()} �$B$rMQ$$$F�(B, reduction �$B$9$kA0$N85�(B, �$B$*$h$SM>$j$N�(B
! 621: �$B%7%U%HIU$-�(B $(u,v)$-order �$B$r7W;;$9$k�(B.
! 622: �$B$3$NNc$G$O�(B, �$BN>J}$H$b�(B $0$ �$B$G$"$k�(B.
! 623: {\footnotesize
! 624: \begin{verbatim}
! 625: vdegree of the original = 0
! 626: vdegree of the remainder = 0
! 627: \end{verbatim}
! 628: }
! 629: �$B$7$?$,$C$F�(B, modulo $(u,v)$-�$B%U%#%k%?!<$G$b�(B $0$ �$B$G$J$$�(B.
1.1 takayama 630:
1.3 ! takayama 631: �$B=`Hw@bL@$,$*$o$C$?�(B. �$B:G=i$N%W%m%0%i%`�(B {\tt SlaScala()} �$B$N@bL@$KLa$k�(B.
! 632: {\tt SpairAndReduction()} �$B$NLa$jCM�(B
! 633: {\tt f[0]} �$B$K$O�(B, reduction �$B$7$?M>$j�(B,
! 634: {\tt f[4]}, {\tt f[5]} �$B$K$O�(B,
! 635: reduction �$B$9$kA0$N85�(B, �$B$*$h$SM>$j$N�(B
! 636: �$B%7%U%HIU$-�(B $(u,v)$-order �$B$,3JG<$5$l$F$$$k�(B.
! 637: �$B$3$NNc$N>l9g$K$O�(B (�$B$m�(B) �$B$N>l9g$,<B9T$5$l$F�(B,
! 638: �$BIU?o$7$?�(B syzygy �$B$O�(B �$B6K>.<+M3J,2r$K$OITMW$J$b$N$H$7$F�(B
! 639: {\tt redundantTable} �$B$KEPO?$5$l$k�(B:
! 640: {\footnotesize
! 641: \begin{verbatim}
! 642: redundantTable[level-1,place] = redundant_seq;
! 643: \end{verbatim}
! 644: } \noindent
! 645: �$BM>$j�(B {\tt f[0]} �$B$O�(B, laScala �$B$N%"%k%4%j%:%`$N�(B 2 �$BG\$*F@8=>]$GF@$i$l$?�(B,
! 646: �$B?7$7$$%V%l%V%J4pDl$N85$G$"$k$,�(B, �$B$3$l$rJ]B8$9$Y$->l=j$N%$%s%G%C%/%9$O�(B,
! 647: �$BLa$jCM�(B {\tt f[3]}({\tt place}) �$B$K3JG<$5$l$F$$$k�(B:
! 648: {\footnotesize
! 649: \begin{verbatim}
! 650: bases[place] = f[0];
! 651: freeRes[level-1] = bases;
! 652: reducer[level-1,place] = f[1];
! 653: \end{verbatim}
! 654: } \noindent
! 655: �$B$3$N�(B reduction �$B$GF@$i$l$?�(B syzygy (�$B$NK\<AE*ItJ,�(B)�$B$O�(B,
! 656: �$BJQ?t�(B {\tt reducer} �$B$KEPO?$5$l$k�(B.
! 657: �$B0J>e$G�(B $(u,v)$-�$B6K>.<+M3J,2rFCM-$N=hM}$NItJ,$N2r@b$r=*$($k�(B.
! 658:
! 659:
! 660: \bigbreak
! 661: �$B0J2<$G$O�(B, LaScala �$B$N%"%k%4%j%:%`$N$o$l$o$l$N<BAu$N35N,$HLdBjE@$r�(B
! 662: �$B=R$Y$k�(B.
! 663:
! 664: �$B$^$:�(B, �$BJQ?t�(B
! 665: {\tt reductionTable} �$B$N0UL#$r@bL@$7$h$&�(B.
! 666: LaScala �$B$N%"%k%4%j%:%`$G$O�(B,
! 667: {\tt level - Sdegree(s)}
! 668: �$B$N>.$5$$�(B S-pair �$B$+$i7W;;$7$F$$$/�(B.
! 669: �$B4X?t�(B {\tt Sdegree} �$B$O<!$N$h$&$K:F5"E*$KDj5A$5$l$F$$$k�(B.
! 670: {\footnotesize
! 671: \begin{verbatim}
! 672: /* f is assumed to be a monomial with toes. */
! 673: def Sdegree(f,tower,level) {
! 674: local i,ww, wd;
! 675: /* extern WeightOfSweyl; */
! 676: ww = WeightOfSweyl;
! 677: f = Init(f);
! 678: if (level <= 1) return(StotalDegree(f));
! 679: i = Degree(f,es);
! 680: return(StotalDegree(f)+Sdegree(tower[level-2,i],tower,level-1));
! 681: }
! 682: \end{verbatim}
! 683: } \noindent
! 684: �$B$3$3$G�(B {\tt StotalDegree(f)} �$B$O�(B $f$ �$B$NA4<!?t$G$"$k�(B.
! 685:
! 686: \noindent
! 687: �$B$5$F�(B, LaScala �$B$N%"%k%4%j%:%`$G$O�(B,
! 688: Resolution �$B$r2<$+$i=gHV$K7W;;$7$F$$$/$N$G$O$J$$�(B.
! 689: �$B$3$l$,K\<AE*$JE@$G$"$k�(B.
! 690: �$B$3$N=gHV$OJQ?t�(B {\tt reductionTable} �$B$K$O$C$F$$$k�(B.
! 691: $I$ �$B$NNc$G$O�(B
! 692: {\footnotesize
! 693: \begin{verbatim}
! 694: reductionTable= [
! 695: [ 1 , 2 , 3 , 4 ]
! 696: [ 3 , 4 , 3 , 2 ] skel[0] �$B$KBP1~�(B
! 697: [ 3 ] skel[1] �$B$KBP1~�(B
! 698: ]
! 699: \end{verbatim}
! 700: } \noindent
! 701: �$B$H$J$k�(B.
! 702:
! 703: �$B8=:_$N<BAu$G$N7W;;B.EY�(B, �$B%a%b%j;HMQNL$N%\%H%k%M%C%/$r�(B
! 704: �$B;XE&$7$F$*$/�(B.
! 705: LaScala �$B$N%"%k%4%j%:%`$G$O�(B, Schreyer Frame �$B$r9=@.$7$F$+$i�(B,
! 706: �$B6K>.<+M3J,2r$r9=@.$9$k�(B.
! 707: �$B2<5-$N%W%m%0%i%`$NJQ?t�(B {\tt redundantTable[level,q]} �$B$K$O�(B,
! 708: �$BBP1~$9$k�(B syzygy �$B$H�(B �$B%0%l%V%J4pDl$N85$,2?2sL\$N�(B reduction �$B$G@8@.�(B
! 709: �$B$5$l$?$+$N?t$,$O$$$C$F$$$k�(B.
! 710: �$B6K>.<+M3J,2r$N9=@.$G$O�(B, �$B:G8e$N�(B reduction �$B$N�(B syzygy �$B$+$i;O$a$F�(B,
! 711: Schreyer resolution �$B$+$i6K>.<+M3J,2r$K$H$C$FM>J,$J85$r<h$j=|$$$F�(B
! 712: �$B$$$/�(B
! 713: ({\tt seq} �$B$r�(B $1$ �$B$E$D8:$i$7$F$$$/�(B).
! 714: {\footnotesize
1.1 takayama 715: \begin{verbatim}
1.3 ! takayama 716: def Sminimal(g,opt) {
! 717:
! 718: ....
! 719:
! 720: while (seq > 1) {
! 721: seq--;
! 722: for (level = 0; level < maxLevel; level++) {
! 723: betti = Length(freeRes[level]);
! 724: for (q = 0; q<betti; q++) {
! 725: if (redundantTable[level,q] == seq) {
! 726: Print("[seq,level,q]="); Println([seq,level,q]);
! 727: if (level < maxLevel-1) {
! 728: bases = freeRes[level+1];
! 729: dr = reducer[level,q];
! 730: dr[q] = -1;
! 731: newbases = SnewArrayOfFormat(bases);
! 732: betti_levelplus = Length(bases);
! 733: /*
! 734: bases[i,j] ---> bases[i,j]+bases[i,q]*dr[j]
! 735: */
! 736: for (i=0; i<betti_levelplus; i++) {
! 737: newbases[i] = bases[i] + bases[i,q]*dr;
! 738: }
! 739: ....
! 740: }
! 741: ....
! 742: }
! 743: }
! 744: }
! 745: }
! 746: ....
! 747: }
1.1 takayama 748: \end{verbatim}
1.3 ! takayama 749: } \noindent
! 750: �$BLdBj$O�(B,
! 751: �$B6K>.<+M3J,2r<+BN$O$A$$$5$/$F$b�(B, Schreyer Frame �$B$,5pBg�(B ($10000$ �$BDxEY$N�(B
! 752: betti �$B?t�(B) �$B$H$J$k$3$H$bB?$$>l9g$,$"$k$3$H$G$"$k�(B.
! 753: �$B2<$NJQ?t�(B {\tt bases} �$B$K�(B, Schreyer resolution �$B$N�(B {\tt level} �$B<!$N�(B
! 754: syzygy �$B$r$$$l$F$$$k�(B. Schreyer Frame �$B$K�(B $10000$ �$BDxEY$N�(B betti
! 755: �$B?t$,$"$i$o$l$k$H$3$NJQ?t$O�(B �$B%5%$%:�(B $10000$ �$BDxEY$NG[Ns$H$J$k�(B.
! 756: �$B$5$i$K�(B, Schreyer �$BJ,2r$+$i6K>.<+M3J,2r$N$?$a$KITMW$J85$r$H$j$N$>$$$?�(B
! 757: �$BJ,2r$r:n$k$?$a$K�(B\\
! 758: \verb# newbases[i] = bases[i] + bases[i,q]*dr; # \\
! 759: �$B$J$k>C5n$r$*$3$J$$�(B, $0$ �$B$GKd$a$i$l$?Ns$^$?$O�(B $0$ �$B$GKd$a$i$l$?9T$r@8@.$7$F$$$k�(B.
! 760: �$B$3$NItJ,$,�(B, �$B%a%b%j$N;HMQ$r05Gw$7$F$*$j�(B, �$B7W;;;~4V$b$D$+$C$F$$$k�(B.
! 761:
1.1 takayama 762:
763:
764: \end{document}
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