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Diff for /OpenXM/src/asir-doc/parts/algnum.texi between version 1.7 and 1.8

-version 1.7, 2003/04/20 08:01:24
+version 1.8, 2007/02/15 02:41:38
 Line 1
 Line 1
 Line 1
- @comment $OpenXM: OpenXM/src/asir-doc/parts/algnum.texi,v 1.6 2003/04/19 15:44:55 noro Exp $
+ @comment $OpenXM: OpenXM/src/asir-doc/parts/algnum.texi,v 1.7 2003/04/20 08:01:24 noro Exp $
  \BJP
  @node $BBe?tE*?t$K4X$9$k1i;;(B,,, Top
  @chapter $BBe?tE*?t$K4X$9$k1i;;(B
 Line 11
 Line 11
 Line 11
  @menu
  \BJP
  * $BBe?tE*?t$NI=8=(B::
+ * $BJ,;6B?9`<0$K$h$kBe?tE*?t$NI=8=(B::
  * $BBe?tE*?t$N1i;;(B::
  * $BBe?tBN>e$G$N(B 1 $BJQ?tB?9`<0$N1i;;(B::
  * $BBe?tE*?t$K4X$9$kH!?t$N$^$H$a(B::
  \E
  \BEG
  * Representation of algebraic numbers::
+ * Representation of algebraic numbers by distributed polynomials::
  * Operations over algebraic numbers::
  * Operations for uni-variate polynomials over an algebraic number field::
  * Summary of functions for algebraic numbers::
-Line 237  t#0
+Line 239  t#0
 Line 237  t#0
 Line 239  t#0
  [100]
  @end example
+ @example
+ @end example
  \BJP
  @node $BBe?tE*?t$N1i;;(B,,, $BBe?tE*?t$K4X$9$k1i;;(B
  @section $BBe?tE*?t$N1i;;(B
-Line 446  used for your own simplification.
+Line 452  used for your own simplification.
 Line 446  used for your own simplification.
 Line 452  used for your own simplification.
  \E
  \BJP
+ @node $BJ,;6B?9`<0$K$h$kBe?tE*?t$NI=8=(B,,, $BBe?tE*?t$K4X$9$k1i;;(B
+ @section $BJ,;6B?9`<0$K$h$kBe?tE*?t$NI=8=(B
+ \E
+ \BEG
+ @node Representation of algebraic numbers by distributed polynomials,,, Algebraic numbers
+ @section Representation of algebraic numbers by distributed polynomials
+ \E
+ @noindent
+ \BJP
+ $BA0@a$G=R$Y$?$h$&$K(B, @code{root} $B$r4^$`Be?tE*?t$KBP$9$k4JC12=$O(B
+ $B%f!<%6$NH=CG$G9T$&I,MW$,$"$k(B. $B$3$l$KBP$7(B, $B$3$3$G2r@b$9$k$b$&0l$D$NBe?tE*?t$N(B
+ $BI=8=$K$D$$$F$O(B, $B2C8:>h=|(B, $B%Y%-$J$I$r9T$C$?$"$H<+F0E*$K4JC12=$,9T$o$l$k(B.
+ $B$3$NI=8=$O(B, $BC`<!3HBg$N>l9g$KFC$K8zN($h$/7W;;$,9T$o$l$k$h$&@_7W$5$l$F$*$j(B,
+ $B%0%l%V%J!<4pDl4X78$N4X?t$K$*$1$k78?tBN$H$7$FMQ$$$k$3$H$,$G$-$k(B. $B$3$NI=8=$O(B
+ $BFbItE*$K$O(B, @code{DAlg} $B$H8F$P$l$k%*%V%8%'%/%H$H$7$FDj5A$5$l$F$$$k(B.
+ @code{DAlg} $B$OJ,?t<0$N7A$GJ];}$5$l$k(B. $BJ,Jl$O@0?t(B, $BJ,;R$O@0?t78?t$NJ,;6B?9`<0$G$"$k(B.
+ \E
+ \BEG
+ Simplification of algebraic numbers containing @code{root}
+ is not done automatically and should be done by users.
+ There is another representation of algebraic numbers, for which the
+ results of fundamental operations are automatically simplified.
+ This representations are designed so that operations are efficiently
+ performed especially when the field is a successive extension and
+ it can be used as a ground field for Groebner basis related functions.
+ Internally an algebraic number of this type is defined as an object
+ called @code{DAlg}. A @code{DAlg} is represented as a fraction. The
+ denominator is an integer and the numerator is a distributed polynomial
+ with integral coefficients.
+ \E
+ \BJP
+ @code{DAlg} $B$O!$(B@code{set_field()} $B$K$h$j$"$i$+$8$a@_Dj$5$l$?Be?tBN$N(B
+ $B85$H$7$F@8@.$5$l$k(B. $B@8@.J}K!$O(B, @code{newalg()} $B$G@8@.$5$l$?Be?tE*?t$r(B
+ $B4^$`?t$+$i(B @code{algtodalg()} $B$GJQ49$9$k(B, $B$"$k$$$OJ,;6B?9`<0$+$iD>@\(B
+ @code{dptodalg()} $B$GJQ49$9$k!$$N(B 2 $BDL$j$"$k(B.
+ $B0lC6(B @code{DAlg} $B7A<0$KJQ49$5$l$l$P(B, $B1i;;8e$K<+F0E*$K4JC12=$5$l$k(B.
+ \E
+ \BEG
+ @code{DAlg} is generated as an element of an algebraic number field
+ set by @code{set_field()}. There are two methods to generate a @code{DAlg}.
+ @code{algtodalg()} converts an algebraic number containing @code{root}
+ to @code{DAlg}. @code{dptodalg()} directly converts a distributed polynomial to
+ @code{DAlg}.
+ \E
+ @example
+ [0] A=newalg(x^2+1);
+ (#0)
+ [1] B=newalg(x^3+A*x+A);
+ (#1)
+ [2] set_field([B,A]);
+ [3] C=algtodalg(A+B);
+ ((1)*<<1,0>>+(1)*<<0,1>>)
+ [4] C^5;
+ ((-11)*<<2,1>>+(5)*<<2,0>>+(10)*<<1,1>>+(9)*<<1,0>>+(11)*<<0,1>>
+ +(-1)*<<0,0>>)
+ [5] 1/C;
+ ((2)*<<2,1>>+(-1)*<<2,0>>+(1)*<<1,1>>+(2)*<<1,0>>+(-3)*<<0,1>>
+ +(-1)*<<0,0>>)/5
+ @end example
+ \BJP
+ $B$3$NNc$G$O(B, Q(a,b) (a^2+1=0, b^3+ab+b=0) $B$K$*$$$F(B, (a+b)^5 $B$*$h$S(B 1/(a+b) $B$r(B
+ $B7W;;(B ($B4JC12=(B) $B$7$F$$$k(B. $BJ,;R$G$"$kJ,;6B?9`<0$NI=<($O(B, $BJ,;6B?9`<0$NI=<($r$=$N$^$^N.MQ$7$F$$$k(B.
+ \E
+ \BEG
+ In this example Q(a,b) (a^2+1=0, b^3+ab+b=0) is set as the current ground field,
+ and (a+b)^5 and 1/(a+b) are simplified in the field. The numerators of the results
+ are printed as distributed polynomials.
+ \E
+ \BJP
  @node $BBe?tBN>e$G$N(B 1 $BJQ?tB?9`<0$N1i;;(B,,, $BBe?tE*?t$K4X$9$k1i;;(B
  @section $BBe?tBN>e$G$N(B 1 $BJQ?tB?9`<0$N1i;;(B
  \E
-Line 710  may yield a polynomial which differs by a constant.
+Line 789  may yield a polynomial which differs by a constant.
 Line 710  may yield a polynomial which differs by a constant.
 Line 789  may yield a polynomial which differs by a constant.
  * sp_norm::
  * asq af af_noalg::
  * sp sp_noalg::
+ * set_field::
+ * algtodalg dalgtoalg dptodalg dalgtodp::
  @end menu
  \JP @node newalg,,, $BBe?tE*?t$K4X$9$kH!?t$N$^$H$a(B
-Line 1451  the builtin function @code{res()} is always used.
+Line 1532  the builtin function @code{res()} is always used.
 Line 1451  the builtin function @code{res()} is always used.
 Line 1532  the builtin function @code{res()} is always used.
  @fref{asq af af_noalg}, @fref{defpoly}, @fref{algptorat}, @fref{sp_norm}.
  @end table
+ \JP @node set_field,,, $BBe?tE*?t$K4X$9$kH!?t$N$^$H$a(B
+ \EG @node set_field,,, Summary of functions for algebraic numbers
+ @subsection @code{set_field}
+ @findex set_field
+ @table @t
+ @item set_field(@var{rootlist})
+ \JP :: $BBe?tBN$r4pACBN$H$7$F@_Dj$9$k(B.
+ \EG :: Set an algebraic number field as the currernt ground field.
+ @end table
+ @table @var
+ @item return
+ @item rootlist
+ \JP @code{root} $B$N%j%9%H(B
+ \EG A list of @code{root}
+ @end table
+ @itemize @bullet
+ @item
+ \JP @code{root} $B$N%j%9%H(B @var{rootlist} $B$G@8@.$5$l$kBe?tBN$r4pACBN$H$7$F@_Dj$9$k(B.
+ \BEG
+ @code{set_field()} sets an algebraic number field generated by @code{root} in
+ @var{rootlist} over Q.
+ \E
+ @item
+ \BJP
+ @code{root} $B$OFbItE*$K=g=x$E$1$i$l$F$$$k$N$G(B, @var{rootlist} $B$O=89g$H$7$F;XDj(B
+ $B$9$l$P$h$$(B. ($B=g=x$O5$$K$7$J$/$F$h$$(B.)
+ \E
+ \BEG
+ You don't care about the order of @code{root} in @var{rootlist}, because
+ @code{root} are automatically ordered internally.
+ \E
+ @end itemize
+ @example
+ [0] A=newalg(x^2+1);
+ (#0)
+ [1] B=newalg(x^3+A);
+ (#1)
+ [2] C=newalg(x^4+B);
+ (#1)
+ [3] set_field([C,B,A]);
+ @end example
+ @table @t
+ \JP @item $B;2>H(B
+ \EG @item Reference
+ @fref{algtodalg dalgtoalg dptodalg dalgtodp}
+ @end table
+ \JP @node algtodalg dalgtoalg dptodalg dalgtodp,,, $BBe?tE*?t$K4X$9$kH!?t$N$^$H$a(B
+ \EG @node algtodalg dalgtoalg dptodalg dalgtodp,,, Summary of functions for algebraic numbers
+ @subsection @code{algtodalg}, @code{dalgtoalg}, @code{dptodalg}, @code{dalgtodp}
+ @findex algtodalg
+ @findex dalgtoalg
+ @findex dpodalg
+ @findex dalgtodp
+ @table @t
+ @item algtodalg(@var{alg})
+ \JP :: $BBe?tE*?t(B @var{alg} $B$r(B @code{DAlg} $B$KJQ49$9$k(B.
+ \EG :: Converts an algebraic number @var{alg} to a @code{DAlg}.
+ @item dalgtoalg(@var{dalg})
+ \JP :: @code{DAlg} @code{dalg} $B$rBe?tE*?t$KJQ49$9$k(B.
+ \EG :: Converts a @code{DAlg} @code{dalg} to an algebraic number.
+ @item dptodalg(@var{dp})
+ \JP :: $BJ,;6B?9`<0(B @var{dp} $B$r(B @code{DAlg} $B$KJQ49$9$k(B.
+ \EG :: Converts an algebraic number @var{alg} to a @code{DAlg}.
+ @item dalgtodp(@var{dalg})
+ \JP :: @code{DAlg} @code{dalg} $B$rJ,;6B?9`<0$KJQ49$9$k(B.
+ \EG :: Converts a @code{DAlg} @code{dalg} to an algebraic number.
+ @end table
+ @table @var
+ @item return
+ \JP $BBe?tE*?t(B, @code{DAlg} $B$^$?$O(B [$BJ,;6B?9`<0(B,$BJ,Jl(B] $B$J$k%j%9%H(B
+ \EG An algebraic number, a @code{DAlg} or a list [distributed polynomial,denominator]
+ @item alg
+ \JP  @code{root} $B$r4^$`Be?tE*?t(B
+ \EG an algebraic number containing @code{root}
+ @item dp
+ \JP  $BM-M}?t78?tJ,;6B?9`<0(B
+ \EG a distributed polynomial over Q
+ @end table
+ @itemize @bullet
+ @item
+ \JP @code{root} $B$r4^$`Be?tE*?t(B, @code{DAlg} $B$*$h$SJ,;6B?9`<04V$NJQ49$r9T$&(B.
+ \BEG
+ These functions are converters between @code{DAlg} and an algebraic number
+ containing @code{root}, or a distributed polynomial.
+ \E
+ @item
+ \BJP
+ @code{DAlg} $B$,B0$9$Y$-Be?tBN$O(B, @code{set_field()} $B$K$h$j(B
+ $B$"$i$+$8$a@_Dj$7$F$*$/I,MW$,$"$k(B.
+ \E
+ \BEG
+ A ground field to which a @code{DAlg} belongs must be set by @code{set_field()}
+ in advance.
+ \E
+ @item
+ \BJP
+ @code{dalgtodp()} $B$O(B, $BJ,;R$G$"$k@0?t78?tJ,;6B?9`<0$H(B, $BJ,Jl$G$"$k@0?t$rMWAG$K;}$D(B
+ $B%j%9%H$rJV$9(B.
+ \E
+ \BEG
+ @code{dalgtodp()} returns a list containing the numerator (a distributed polynomial)
+ and the denominator (an integer).
+ \E
+ @item
+ \BJP
+ @code{algtodalg()}, @code{dptodalg()} $B$O4JC12=$5$l$?7k2L$rJV$9(B.
+ \E
+ \BEG
+ @code{algtodalg()}, @code{dptodalg()} return the simplified result.
+ \E
+ @end itemize
+ @example
+ [0] A=newalg(x^2+1);
+ (#0)
+ [1] B=newalg(x^3+A*x+A);
+ (#1)
+ [2] set_field([B,A]);
+ [3] C=algtodalg((A+B)^10);
+ ((408)*<<2,1>>+(103)*<<2,0>>+(-36)*<<1,1>>+(-446)*<<1,0>>
+ +(-332)*<<0,1>>+(-218)*<<0,0>>)
+ [4] dalgtoalg(C);
+ ((408*#0+103)*#1^2+(-36*#0-446)*#1-332*#0-218)
+ [5] D=dptodalg(<<10,10>>/10+2*<<5,5>>+1/3*<<0,0>>);
+ ((-9)*<<2,1>>+(57)*<<2,0>>+(-63)*<<1,1>>+(-12)*<<1,0>>
+ +(-60)*<<0,1>>+(1)*<<0,0>>)/30
+ [6] dalgtodp(D);
+ [(-9)*<<2,1>>+(57)*<<2,0>>+(-63)*<<1,1>>+(-12)*<<1,0>>
+ +(-60)*<<0,1>>+(1)*<<0,0>>,30]
+ @end example
+ @table @t
+ \JP @item $B;2>H(B
+ \EG @item Reference
+ @fref{set_field}
+ @end table

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