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Diff for /OpenXM/src/asir-doc/parts/algnum.texi between version 1.3 and 1.4

version 1.3, 2000/03/10 07:18:40

version 1.4, 2000/03/17 02:17:03

Line 1

@comment $OpenXM: OpenXM/src/asir-doc/parts/algnum.texi,v 1.2 1999/12/21 02:47:30 noro Exp $

@comment $OpenXM: OpenXM/src/asir-doc/parts/algnum.texi,v 1.3 2000/03/10 07:18:40 noro Exp $

\BJP

@node $BBe?tE*?t$K4X$9$k1i;;(B,,, Top

@chapter $BBe?tE*?t$K4X$9$k1i;;(B

Line 706 may yield a polynomial which differs by a constant.

* rattoalgp::

* cr_gcda::

* sp_norm::

* asq af::

* asq af af_noalg::

* sp::

* sp sp_noalg::

@end menu

\JP @node newalg,,, $BBe?tE*?t$K4X$9$kH!?t$N$^$H$a(B

Line 1109 x+(-#0)

@table @t

\JP @item $B;2>H(B

\EG @item Reference

@fref{gr hgr gr_mod}, @fref{asq af}

@fref{gr hgr gr_mod}, @fref{asq af af_noalg}

@end table

\JP @node sp_norm,,, $BBe?tE*?t$K4X$9$kH!?t$N$^$H$a(B

Line 1192 x^12+2*x^8+5*x^4+1

@table @t

\JP @item $B;2>H(B

\EG @item Reference

@fref{res}, @fref{asq af}

@fref{res}, @fref{asq af af_noalg}

@end table

\JP @node asq af,,, $BBe?tE*?t$K4X$9$kH!?t$N$^$H$a(B

\JP @node asq af af_noalg,,, $BBe?tE*?t$K4X$9$kH!?t$N$^$H$a(B

\EG @node asq af,,, Summary of functions for algebraic numbers

\EG @node asq af af_noalg,,, Summary of functions for algebraic numbers

@subsection @code{asq}, @code{af}

@subsection @code{asq}, @code{af}, @code{af_noalg}

@findex asq

@findex af

@findex af_noalg

@table @t

@item asq(@var{poly})

Line 1209 x^12+2*x^8+5*x^4+1

Line 1210 x^12+2*x^8+5*x^4+1

algebraic number field.

@item af(@var{poly},@var{alglist})

@itemx af_noalg(@var{poly},@var{defpolylist})

\JP :: $BBe?tBN>e$N(B 1 $BJQ?tB?9`<0$N0x?tJ,2r(B

\BEG

:: Factorization of polynomial @var{poly} over an

Line 1226 algebraic number field.

Line 1228 algebraic number field.

@item alglist

\JP @code{root} $B$N%j%9%H(B

\EG @code{root} list

@item defpolylist

\JP @code{root} $B$rI=$9ITDj85$HDj5AB?9`<0$N%Z%"$N%j%9%H(B

\EG @code{root} list of pairs of an indeterminate and a polynomial

@end table

@itemize @bullet

Line 1263 In the second argument @code{alglist}, @b{root} define

Line 1268 In the second argument @code{alglist}, @b{root} define

first.

@item

\JP $B7k2L$O(B, $BDL>o$NL5J?J}J,2r(B, $B0x?tJ,2r$HF1MM(B [@b{$B0x;R(B}, @b{$B=EJ#EY(B}] $B$N%j%9%H$G$"$k(B.

\BJP

@code{sp_noalg} $B$G$O(B, @var{poly} $B$K4^$^$l$kBe?tE*?t(B @var{ai} $B$rITDj85(B @var{vi}

$B$GCV$-49$($k(B. @code{defpolylist} $B$O(B, @var{[[vn,dn(vn,...,v1)],...,[v1,d(v1)]]}

$B$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.

\BEG

To call @code{sp_noalg}, one should replace each algebraic number

@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

@var{di(vi,...,v1)} is a defining polynomial of @var{ai} represented

as a multivariate polynomial.

@item

\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}]

$B$N%j%9%H$G$"$k(B. @code{af_noalg} $B$N>l9g(B, @b{$B0x;R(B} $B$K8=$l$kBe?tE*?t$O(B,

@var{defpolylist} $B$K=>$C$FITDj85$KCV$-49$($i$l$k(B.

\BEG

The result is a list, as a result of usual factorization, whose elements

is of the form [@b{factor}, @b{multiplicity}].

In the result of @code{af_noalg}, algebraic numbers in @v{factor} are

replaced by the indeterminates according to @var{defpolylist}.

@item

\JP $B=EJ#EY$r9~$a$?0x;R$NA4$F$N@Q$O(B, @var{poly} $B$HDj?tG\$N0c$$$,$"$jF@$k(B.

Line 1289 the input polynomial by a constant.

Line 1314 the input polynomial by a constant.

@fref{cr_gcda}, @fref{fctr sqfr}

@end table

\JP @node sp,,, $BBe?tE*?t$K4X$9$kH!?t$N$^$H$a(B

\JP @node sp sp_noalg,,, $BBe?tE*?t$K4X$9$kH!?t$N$^$H$a(B

\EG @node sp,,, Summary of functions for algebraic numbers

\EG @node sp sp_noalg,,, Summary of functions for algebraic numbers

@subsection @code{sp}

@subsection @code{sp}, @code{sp_noalg}

@findex sp

@table @t

@item sp(@var{poly})

@itemx sp_noalg(@var{poly})

\JP :: $B:G>.J,2rBN$r5a$a$k(B.

\EG :: Finds the splitting field of polynomial @var{poly} and splits.

@end table

Line 1326 over the field.

Line 1352 over the field.

@item

\BJP

$B7k2L$O(B, @var{poly} $B$N0x;R$N%j%9%H$H(B, $B:G>.J,2rBN$N(B, $BC`<!3HBg$K$h$kI=8=(B

$B$+$i$J$k%j%9%H$G$"$k(B.

$B$+$i$J$k%j%9%H$G$"$k(B. @code{sp_noalg} $B$G$O(B, $BA4$F$NBe?tE*?t$,(B, $BBP1~$9$k(B

$BITDj85(B ($BB($A(B @code{#i} $B$KBP$9$k(B @code{t#i}) $B$KCV$-49$($i$l$k(B. $B$3$l$K(B

$B$h$j(B, @code{sp_noalg} $B$N=PNO$O(B, $B@0?t78?tB?JQ?tB?9`<0$N%j%9%H$H$J$k(B.

\BEG

The result consists of a two element list: The first element is

the list of all linear factors of @var{poly}; the second element is

a list which represents the successive extension of the field.

In the result of @code{sp_noalg} all the algebraic numbers are replaced

by the special indeterminate associated with it, that is @code{t#i}

for @code{#i}. By this operation the result of @code{sp_noalg}

is a list containing only integral polynomials.

@item

\BJP

Line 1382 the builtin function @code{res()} is always used.

Line 1414 the builtin function @code{res()} is always used.

@table @t

\JP @item $B;2>H(B

\EG @item Reference

@fref{asq af}, @fref{defpoly}, @fref{algptorat}, @fref{sp_norm}.

@fref{asq af af_noalg}, @fref{defpoly}, @fref{algptorat}, @fref{sp_norm}.

@end table

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