| version 1.4, 2000/03/17 02:17:03 |
version 1.7, 2003/04/20 08:01:24 |
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| @comment $OpenXM: OpenXM/src/asir-doc/parts/algnum.texi,v 1.3 2000/03/10 07:18:40 noro Exp $ |
@comment $OpenXM: OpenXM/src/asir-doc/parts/algnum.texi,v 1.6 2003/04/19 15:44:55 noro Exp $ |
| \BJP |
\BJP |
| @node �$BBe?tE*?t$K4X$9$k1i;;�(B,,, Top |
@node �$BBe?tE*?t$K4X$9$k1i;;�(B,,, Top |
| @chapter �$BBe?tE*?t$K4X$9$k1i;;�(B |
@chapter �$BBe?tE*?t$K4X$9$k1i;;�(B |
| Line 410 into the @b{root} by @code{rattoalgp()} function. |
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| Line 410 into the @b{root} by @code{rattoalgp()} function. |
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| |
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| @example |
@example |
| [88] rattoalgp(S,[alg(0)]); |
[88] rattoalgp(S,[alg(0)]); |
| (((#0+2)/(#0+2))*t#1^2+((#0^2+2*#0)/(#0+2))*t#1+((2*#0^2+4*#0)/(#0+2)))*x |
(((#0+2)/(#0+2))*t#1^2+((#0^2+2*#0)/(#0+2))*t#1 |
| +((1)/(#0+2))*t#1+((1)/(#0+2)) |
+((2*#0^2+4*#0)/(#0+2)))*x+((1)/(#0+2))*t#1+((1)/(#0+2)) |
| [89] rattoalgp(S,[alg(0),alg(1)]); |
[89] rattoalgp(S,[alg(0),alg(1)]); |
| (((#0^3+6*#0^2+12*#0+8)*#1^2+(#0^4+6*#0^3+12*#0^2+8*#0)*#1+2*#0^4+12*#0^3 |
(((#0^3+6*#0^2+12*#0+8)*#1^2+(#0^4+6*#0^3+12*#0^2+8*#0)*#1 |
| +24*#0^2+16*#0)/(#0^3+6*#0^2+12*#0+8))*x+(((#0+2)*#1+#0+2)/(#0^2+4*#0+4)) |
+2*#0^4+12*#0^3+24*#0^2+16*#0)/(#0^3+6*#0^2+12*#0+8))*x |
| |
+(((#0+2)*#1+#0+2)/(#0^2+4*#0+4)) |
| [90] rattoalgp(S,[alg(1),alg(0)]); |
[90] rattoalgp(S,[alg(1),alg(0)]); |
| (((#0+2)*#1^2+(#0^2+2*#0)*#1+2*#0^2+4*#0)/(#0+2))*x+((#1+1)/(#0+2)) |
(((#0+2)*#1^2+(#0^2+2*#0)*#1+2*#0^2+4*#0)/(#0+2))*x |
| |
+((#1+1)/(#0+2)) |
| [91] simpalg(@@89); |
[91] simpalg(@@89); |
| (#1^2+#0*#1+2*#0)*x+((-1/5*#0+2/5)*#1-1/5*#0+2/5) |
(#1^2+#0*#1+2*#0)*x+((-1/5*#0+2/5)*#1-1/5*#0+2/5) |
| [92] simpalg(@@90); |
[92] simpalg(@@90); |
| Line 499 where the ground field is a multiple extension. |
|
| Line 501 where the ground field is a multiple extension. |
|
| (#0) |
(#0) |
| [64] B=newalg(75*s^2+(10*A^7-175*A^4-470*A)*s+3*A^8-45*A^5-261*A^2); |
[64] B=newalg(75*s^2+(10*A^7-175*A^4-470*A)*s+3*A^8-45*A^5-261*A^2); |
| (#1) |
(#1) |
| [65] P1=75*x^2+(150*B+10*A^7-175*A^4-395*A)*x+(75*B^2+(10*A^7-175*A^4-395*A)*B |
[65] P1=75*x^2+(150*B+10*A^7-175*A^4-395*A)*x |
| +13*A^8-220*A^5-581*A^2)$ |
+(75*B^2+(10*A^7-175*A^4-395*A)*B+13*A^8-220*A^5-581*A^2)$ |
| [66] P2=x^2+A*x+A^2$ |
[66] P2=x^2+A*x+A^2$ |
| [67] cr_gcda(P1,P2); |
[67] cr_gcda(P1,P2); |
| 27*x+((#0^6-19*#0^3-65)*#1-#0^7+19*#0^4+38*#0) |
27*x+((#0^6-19*#0^3-65)*#1-#0^7+19*#0^4+38*#0) |
| Line 531 The function to do this factorization is @code{asq()}. |
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| Line 533 The function to do this factorization is @code{asq()}. |
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| [116] A=newalg(x^2+x+1); |
[116] A=newalg(x^2+x+1); |
| (#4) |
(#4) |
| [117] T=simpalg((x+A+1)*(x^2-2*A-3)^2*(x^3-x-A)^2); |
[117] T=simpalg((x+A+1)*(x^2-2*A-3)^2*(x^3-x-A)^2); |
| x^11+(#4+1)*x^10+(-4*#4-8)*x^9+(-10*#4-4)*x^8+(16*#4+20)*x^7+(24*#4-6)*x^6 |
x^11+(#4+1)*x^10+(-4*#4-8)*x^9+(-10*#4-4)*x^8+(16*#4+20)*x^7 |
| +(-29*#4-31)*x^5+(-15*#4+28)*x^4+(38*#4+29)*x^3+(#4-23)*x^2+(-21*#4-7)*x |
+(24*#4-6)*x^6+(-29*#4-31)*x^5+(-15*#4+28)*x^4+(38*#4+29)*x^3 |
| +(3*#4+8) |
+(#4-23)*x^2+(-21*#4-7)*x+(3*#4+8) |
| [118] asq(T); |
[118] asq(T); |
| [[x^5+(-2*#4-4)*x^3+(-#4)*x^2+(2*#4+3)*x+(#4-2),2],[x+(#4+1),1]] |
[[x^5+(-2*#4-4)*x^3+(-#4)*x^2+(2*#4+3)*x+(#4-2),2],[x+(#4+1),1]] |
| @end example |
@end example |
| Line 641 The function is @code{sp()}. |
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| Line 643 The function is @code{sp()}. |
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| |
|
| @example |
@example |
| [103] sp(x^5-2); |
[103] sp(x^5-2); |
| [[x+(-#1),2*x+(#0^3*#1^3+#0^4*#1^2+2*#1+2*#0),2*x+(-#0^4*#1^2),2*x |
[[x+(-#1),2*x+(#0^3*#1^3+#0^4*#1^2+2*#1+2*#0),2*x+(-#0^4*#1^2), |
| +(-#0^3*#1^3),x+(-#0)],[[(#1),t#1^4+t#0*t#1^3+t#0^2*t#1^2+t#0^3*t#1+t#0^4], |
2*x+(-#0^3*#1^3),x+(-#0)], |
| [(#0),t#0^5-2]]] |
[[(#1),t#1^4+t#0*t#1^3+t#0^2*t#1^2+t#0^3*t#1+t#0^4],[(#0),t#0^5-2]]] |
| @end example |
@end example |
| |
|
| @noindent |
@noindent |
| Line 1083 substitutes a @b{root} for the associated indeterminat |
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| Line 1085 substitutes a @b{root} for the associated indeterminat |
|
| @item return |
@item return |
| \JP �$BB?9`<0�(B |
\JP �$BB?9`<0�(B |
| \EG polynomial |
\EG polynomial |
| @item poly1, poly2 |
@item poly1 poly2 |
| \JP �$BB?9`<0�(B |
\JP �$BB?9`<0�(B |
| \EG polynomial |
\EG polynomial |
| @end table |
@end table |
|
|
| \E |
\E |
| @item |
@item |
| \BJP |
\BJP |
| @code{sp_noalg} �$B$G$O�(B, @var{poly} �$B$K4^$^$l$kBe?tE*?t�(B @var{ai} �$B$rITDj85�(B @var{vi} |
@code{af(F,AL)} �$B$K$*$$$F�(B, @code{AL} �$B$OBe?tE*?t$N%j%9%H$G$"$j�(B, �$BM-M}?tBN$N�(B |
| �$B$GCV$-49$($k�(B. @code{defpolylist} �$B$O�(B, @var{[[vn,dn(vn,...,v1)],...,[v1,d(v1)]]} |
�$BBe?t3HBg$rI=$9�(B. @code{AL=[An,...,A1]} �$B$H=q$/$H$-�(B, �$B3F�(B @code{Ak} �$B$O�(B, �$B$=$l$h$j�(B |
| �$B$J$k%j%9%H$G$"$k�(B. �$B$3$3$G�(B @var{di(vi,...,v1)} �$B$O�(B @var{ai} �$B$NDj5AB?9`<0$K$*$$$F�(B |
�$B1&$K$"$kBe?tE*?t$r78?t$H$7$?�(B, �$B%b%K%C%/$JDj5AB?9`<0$GDj5A$5$l$F$$$J$1$l$P�(B |
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�$B$J$i$J$$�(B. |
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\E |
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\BEG |
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In @code{af(F,AL)}, @code{AL} denotes a list of @code{roots} and it |
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represents an algebraic number field. In @code{AL=[An,...,A1]} each |
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@code{Ak} should be defined as a root of a defining polynomial |
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whose coefficients are in @code{Q(A(k+1),...,An)}. |
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\E |
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|
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@example |
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[1] A1 = newalg(x^2+1); |
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[2] A2 = newalg(x^2+A1); |
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[3] A3 = newalg(x^2+A2*x+A1); |
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[4] af(x^2+A2*x+A1,[A2,A1]); |
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[[x^2+(#1)*x+(#0),1]] |
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@end example |
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|
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\BJP |
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@code{af_noalg} �$B$G$O�(B, @var{poly} �$B$K4^$^$l$kBe?tE*?t�(B @var{ai} �$B$rITDj85�(B @var{vi} |
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�$B$GCV$-49$($k�(B. @code{defpolylist} �$B$O�(B, [[vn,dn(vn,...,v1)],...,[v1,d(v1)]] |
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�$B$J$k%j%9%H$G$"$k�(B. �$B$3$3$G�(B @var{di}(vi,...,v1) �$B$O�(B @var{ai} �$B$NDj5AB?9`<0$K$*$$$F�(B |
| �$BBe?tE*?t$rA4$F�(B @var{vj} �$B$KCV$-49$($?$b$N$G$"$k�(B. |
�$BBe?tE*?t$rA4$F�(B @var{vj} �$B$KCV$-49$($?$b$N$G$"$k�(B. |
| \E |
\E |
| \BEG |
\BEG |
| To call @code{sp_noalg}, one should replace each algebraic number |
To call @code{sp_noalg}, one should replace each algebraic number |
| @var{ai} in @var{poly} with an indeterminate @var{vi}. @code{defpolylist} |
@var{ai} in @var{poly} with an indeterminate @var{vi}. @code{defpolylist} |
| is a list @var{[[vn,dn(vn,...,v1)],...,[v1,d(v1)]]}. In this expression |
is a list [[vn,dn(vn,...,v1)],...,[v1,d(v1)]]. In this expression |
| @var{di(vi,...,v1)} is a defining polynomial of @var{ai} represented |
@var{di}(vi,...,v1) is a defining polynomial of @var{ai} represented |
| as a multivariate polynomial. |
as a multivariate polynomial. |
| \E |
\E |
| |
|
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@example |
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[1] af_noalg(x^2+a2*x+a1,[[a2,a2^2+a1],[a1,a1^2+1]]); |
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[[x^2+a2*x+a1,1]] |
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@end example |
| |
|
| @item |
@item |
| \BJP |
\BJP |
| �$B7k2L$O�(B, �$BDL>o$NL5J?J}J,2r�(B, �$B0x?tJ,2r$HF1MM�(B [@b{�$B0x;R�(B}, @b{�$B=EJ#EY�(B}] |
�$B7k2L$O�(B, �$BDL>o$NL5J?J}J,2r�(B, �$B0x?tJ,2r$HF1MM�(B [@b{�$B0x;R�(B}, @b{�$B=EJ#EY�(B}] |
| Line 1302 the input polynomial by a constant. |
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| Line 1331 the input polynomial by a constant. |
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| @end itemize |
@end itemize |
| |
|
| @example |
@example |
| |
[98] A = newalg(t^2-2); |
| |
(#0) |
| [99] asq(-x^4+6*x^3+(2*alg(0)-9)*x^2+(-6*alg(0))*x-2); |
[99] asq(-x^4+6*x^3+(2*alg(0)-9)*x^2+(-6*alg(0))*x-2); |
| [[-x^2+3*x+(#0),2]] |
[[-x^2+3*x+(#0),2]] |
| [100] af(-x^2+3*x+alg(0),[alg(0)]); |
[100] af(-x^2+3*x+alg(0),[alg(0)]); |
| [[x+(#0-1),1],[-x+(#0+2),1]] |
[[x+(#0-1),1],[-x+(#0+2),1]] |
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[101] af_noalg(-x^2+3*x+a,[[a,x^2-2]]); |
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[[x+a-1,1],[-x+a+2,1]] |
| @end example |
@end example |
| |
|
| @table @t |
@table @t |
| Line 1374 is a list containing only integral polynomials. |
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| Line 1407 is a list containing only integral polynomials. |
|
| \E |
\E |
| \BEG |
\BEG |
| The splitting field is represented as a list of pairs of form |
The splitting field is represented as a list of pairs of form |
| @code{[root,algptorat(defpoly(root))]}. |
@code{[root,} @code{algptorat(defpoly(root))]}. |
| In more detail, the list is interpreted as a representation |
In more detail, the list is interpreted as a representation |
| of successive extension obtained by adjoining @b{root}'s |
of successive extension obtained by adjoining @b{root}'s |
| to the rational number field. Adjoining is performed from the right |
to the rational number field. Adjoining is performed from the right |
| Line 1401 the builtin function @code{res()} is always used. |
|
| Line 1434 the builtin function @code{res()} is always used. |
|
| |
|
| @example |
@example |
| [101] L=sp(x^9-54); |
[101] L=sp(x^9-54); |
| [[x+(-#2),-54*x+(#1^6*#2^4),54*x+(#1^6*#2^4+54*#2),54*x+(-#1^8*#2^2), |
[[x+(-#2),-54*x+(#1^6*#2^4),54*x+(#1^6*#2^4+54*#2), |
| -54*x+(#1^5*#2^5),54*x+(#1^5*#2^5+#1^8*#2^2),-54*x+(-#1^7*#2^3-54*#1), |
54*x+(-#1^8*#2^2),-54*x+(#1^5*#2^5),54*x+(#1^5*#2^5+#1^8*#2^2), |
| 54*x+(-#1^7*#2^3),x+(-#1)],[[(#2),t#2^6+t#1^3*t#2^3+t#1^6],[(#1),t#1^9-54]]] |
-54*x+(-#1^7*#2^3-54*#1),54*x+(-#1^7*#2^3),x+(-#1)], |
| |
[[(#2),t#2^6+t#1^3*t#2^3+t#1^6],[(#1),t#1^9-54]]] |
| [102] for(I=0,M=1;I<9;I++)M*=L[0][I]; |
[102] for(I=0,M=1;I<9;I++)M*=L[0][I]; |
| [111] M=simpalg(M); |
[111] M=simpalg(M); |
| -1338925209984*x^9+72301961339136 |
-1338925209984*x^9+72301961339136 |
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