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\documentclass{article}
\usepackage{open-axiom}
\begin{document}
\title{\$SPAD/src/algebra solvefor.spad}
\author{Stephen M. Watt, Barry Trager}
\maketitle
\begin{abstract}
\end{abstract}
\eject
\tableofcontents
\eject
\section{package SOLVEFOR PolynomialSolveByFormulas}
<<package SOLVEFOR PolynomialSolveByFormulas>>=
)abbrev package SOLVEFOR PolynomialSolveByFormulas
-- Current fields with **: (%, RationalNumber) -> % are
-- ComplexFloat, RadicalExtension(K) and RationalRadical
-- SMW June 86, BMT Sept 93
++ Description:
++ This package factors the formulas out of the general solve code,
++ allowing their recursive use over different domains.
++ Care is taken to introduce few radicals so that radical extension
++ domains can more easily simplify the results.
PolynomialSolveByFormulas(UP, F): PSFcat == PSFdef where
UP: UnivariatePolynomialCategory F
F: Field with **: (%, Fraction Integer) -> %
L ==> List
PSFcat == with
solve: UP -> L F
++ solve(u) \undocumented
particularSolution: UP -> F
++ particularSolution(u) \undocumented
mapSolve: (UP, F -> F) -> Record(solns: L F,
maps: L Record(arg:F,res:F))
++ mapSolve(u,f) \undocumented
linear: UP -> L F
++ linear(u) \undocumented
quadratic: UP -> L F
++ quadratic(u) \undocumented
cubic: UP -> L F
++ cubic(u) \undocumented
quartic: UP -> L F
++ quartic(u) \undocumented
-- Arguments give coefs from high to low degree.
linear: (F, F) -> L F
++ linear(f,g) \undocumented
quadratic: (F, F, F) -> L F
++ quadratic(f,g,h) \undocumented
cubic: (F, F, F, F) -> L F
++ cubic(f,g,h,i) \undocumented
quartic: (F, F, F, F, F) -> L F
++ quartic(f,g,h,i,j) \undocumented
aLinear: (F, F) -> F
++ aLinear(f,g) \undocumented
aQuadratic: (F, F, F) -> F
++ aQuadratic(f,g,h) \undocumented
aCubic: (F, F, F, F) -> F
++ aCubic(f,g,h,j) \undocumented
aQuartic: (F, F, F, F, F) -> F
++ aQuartic(f,g,h,i,k) \undocumented
PSFdef == add
-----------------------------------------------------------------
-- Stuff for mapSolve
-----------------------------------------------------------------
id ==> (IDENTITY$Lisp)
maplist: List Record(arg: F, res: F) := []
mapSolving?: Boolean := false
-- map: F -> F := id #1 replaced with line below
map: Boolean := false
mapSolve(p, fn) ==
-- map := fn #1 replaced with line below
locmap: F -> F := fn #1; map := id locmap
mapSolving? := true; maplist := []
slist := solve p
mapSolving? := false;
-- map := id #1 replaced with line below
locmap := id #1; map := id locmap
[slist, maplist]
part(s: F): F ==
not mapSolving? => s
-- t := map s replaced with line below
t: F := SPADCALL(s, map)$Lisp
t = s => s
maplist := cons([t, s], maplist)
t
-----------------------------------------------------------------
-- Entry points and error handling
-----------------------------------------------------------------
cc ==> coefficient
-- local intsolve
intsolve(u:UP):L(F) ==
u := (factors squareFree u).1.factor
n := degree u
n=1 => linear (cc(u,1), cc(u,0))
n=2 => quadratic (cc(u,2), cc(u,1), cc(u,0))
n=3 => cubic (cc(u,3), cc(u,2), cc(u,1), cc(u,0))
n=4 => quartic (cc(u,4), cc(u,3), cc(u,2), cc(u,1), cc(u,0))
error "All sqfr factors of polynomial must be of degree < 5"
solve u ==
ls := nil$L(F)
for f in factors squareFree u repeat
lsf := intsolve f.factor
for i in 1..(f.exponent) repeat ls := [:lsf,:ls]
ls
particularSolution u ==
u := (factors squareFree u).1.factor
n := degree u
n=1 => aLinear (cc(u,1), cc(u,0))
n=2 => aQuadratic (cc(u,2), cc(u,1), cc(u,0))
n=3 => aCubic (cc(u,3), cc(u,2), cc(u,1), cc(u,0))
n=4 => aQuartic (cc(u,4), cc(u,3), cc(u,2), cc(u,1), cc(u,0))
error "All sqfr factors of polynomial must be of degree < 5"
needDegree(n: Integer, u: UP): Boolean ==
degree u = n => true
error concat("Polynomial must be of degree ", n::String)
needLcoef(cn: F): Boolean ==
cn ~= 0 => true
error "Leading coefficient must not be 0."
needChar0(): Boolean ==
characteristic$F = 0 => true
error "Formula defined only for fields of characteristic 0."
linear u ==
needDegree(1, u)
linear (coefficient(u,1), coefficient(u,0))
quadratic u ==
needDegree(2, u)
quadratic (coefficient(u,2), coefficient(u,1),
coefficient(u,0))
cubic u ==
needDegree(3, u)
cubic (coefficient(u,3), coefficient(u,2),
coefficient(u,1), coefficient(u,0))
quartic u ==
needDegree(4, u)
quartic (coefficient(u,4),coefficient(u,3),
coefficient(u,2),coefficient(u,1),coefficient(u,0))
-----------------------------------------------------------------
-- The formulas
-----------------------------------------------------------------
-- local function for testing equality of radicals.
-- This function is necessary to detect at least some of the
-- situations like sqrt(9)-3 = 0 --> false.
equ(x:F,y:F):Boolean ==
( (recip(x-y)) case "failed" ) => true
false
linear(c1, c0) ==
needLcoef c1
[- c0/c1 ]
aLinear(c1, c0) ==
first linear(c1,c0)
quadratic(c2, c1, c0) ==
needLcoef c2; needChar0()
(c0 = 0) => [0$F,:linear(c2, c1)]
(c1 = 0) => [(-c0/c2)**(1/2),-(-c0/c2)**(1/2)]
D := part(c1**2 - 4*c2*c0)**(1/2)
[(-c1+D)/(2*c2), (-c1-D)/(2*c2)]
aQuadratic(c2, c1, c0) ==
needLcoef c2; needChar0()
(c0 = 0) => 0$F
(c1 = 0) => (-c0/c2)**(1/2)
D := part(c1**2 - 4*c2*c0)**(1/2)
(-c1+D)/(2*c2)
w3: F := (-1 + (-3::F)**(1/2)) / 2::F
cubic(c3, c2, c1, c0) ==
needLcoef c3; needChar0()
-- case one root = 0, not necessary but keeps result small
(c0 = 0) => [0$F,:quadratic(c3, c2, c1)]
a1 := c2/c3; a2 := c1/c3; a3 := c0/c3
-- case x**3-a3 = 0, not necessary but keeps result small
(a1 = 0 and a2 = 0) =>
[ u*(-a3)**(1/3) for u in [1, w3, w3**2 ] ]
-- case x**3 + a1*x**2 + a1**2*x/3 + a3 = 0, the general for-
-- mula is not valid in this case, but solution is easy.
P := part(-a1/3::F)
equ(a1**2,3*a2) =>
S := part((- a3 + (a1**3)/27::F)**(1/3))
[ P + S*u for u in [1,w3,w3**2] ]
-- general case
Q := part((3*a2 - a1**2)/9::F)
R := part((9*a1*a2 - 27*a3 - 2*a1**3)/54::F)
D := part(Q**3 + R**2)**(1/2)
S := part(R + D)**(1/3)
-- S = 0 is done in the previous case
[ P + S*u - Q/(S*u) for u in [1, w3, w3**2] ]
aCubic(c3, c2, c1, c0) ==
needLcoef c3; needChar0()
(c0 = 0) => 0$F
a1 := c2/c3; a2 := c1/c3; a3 := c0/c3
(a1 = 0 and a2 = 0) => (-a3)**(1/3)
P := part(-a1/3::F)
equ(a1**2,3*a2) =>
S := part((- a3 + (a1**3)/27::F)**(1/3))
P + S
Q := part((3*a2 - a1**2)/9::F)
R := part((9*a1*a2 - 27*a3 - 2*a1**3)/54::F)
D := part(Q**3 + R**2)**(1/2)
S := part(R + D)**(1/3)
P + S - Q/S
quartic(c4, c3, c2, c1, c0) ==
needLcoef c4; needChar0()
-- case one root = 0, not necessary but keeps result small
(c0 = 0) => [0$F,:cubic(c4, c3, c2, c1)]
-- Make monic:
a1 := c3/c4; a2 := c2/c4; a3 := c1/c4; a4 := c0/c4
-- case x**4 + a4 = 0 <=> (x**2-sqrt(-a4))*(x**2+sqrt(-a4))
-- not necessary but keeps result small.
(a1 = 0 and a2 = 0 and a3 = 0) =>
append( quadratic(1, 0, (-a4)**(1/2)),_
quadratic(1 ,0, -((-a4)**(1/2))) )
-- Translate w = x+a1/4 to eliminate a1: w**4+p*w**2+q*w+r
p := part(a2-3*a1*a1/8::F)
q := part(a3-a1*a2/2::F + a1**3/8::F)
r := part(a4-a1*a3/4::F + a1**2*a2/16::F - 3*a1**4/256::F)
-- t0 := the cubic resolvent of x**3-p*x**2-4*r*x+4*p*r-q**2
-- The roots of the translated polynomial are those of
-- two quadratics. (What about rt=0 ?)
-- rt=0 can be avoided by picking a root ~= p of the cubic
-- polynomial above. This is always possible provided that
-- the input is squarefree. In this case the two other roots
-- are +(-) 2*r**(1/2).
if equ(q,0) -- this means p is a root
then t0 := part(2*(r**(1/2)))
else t0 := aCubic(1, -p, -4*r, 4*p*r - q**2)
rt := part(t0 - p)**(1/2)
slist := append( quadratic( 1, rt, (-q/rt + t0)/2::F ),
quadratic( 1, -rt, ( q/rt + t0)/2::F ))
-- Translate back:
[s - a1/4::F for s in slist]
aQuartic(c4, c3, c2, c1, c0) ==
needLcoef c4; needChar0()
(c0 = 0) => 0$F
a1 := c3/c4; a2 := c2/c4; a3 := c1/c4; a4 := c0/c4
(a1 = 0 and a2 = 0 and a3 = 0) => (-a4)**(1/4)
p := part(a2-3*a1*a1/8::F)
q := part(a3-a1*a2/2::F + a1**2*a1/8::F)
r := part(a4-a1*a3/4::F + a1**2*a2/16::F - 3*a1**4/256::F)
if equ(q,0)
then t0 := part(2*(r**(1/2)))
else t0 := aCubic(1, -p, -4*r, 4*p*r - q**2)
rt := part(t0 - p)**(1/2)
s := aQuadratic( 1, rt, (-q/rt + t0)/2::F )
s - a1/4::F
@
\section{License}
<<license>>=
--Copyright (c) 1991-2002, The Numerical ALgorithms Group Ltd.
--All rights reserved.
--
--Redistribution and use in source and binary forms, with or without
--modification, are permitted provided that the following conditions are
--met:
--
-- - Redistributions of source code must retain the above copyright
-- notice, this list of conditions and the following disclaimer.
--
-- - Redistributions in binary form must reproduce the above copyright
-- notice, this list of conditions and the following disclaimer in
-- the documentation and/or other materials provided with the
-- distribution.
--
-- - Neither the name of The Numerical ALgorithms Group Ltd. nor the
-- names of its contributors may be used to endorse or promote products
-- derived from this software without specific prior written permission.
--
--THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS
--IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
--TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A
--PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER
--OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
--EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
--PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
--PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
--LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
--NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
--SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
@
<<*>>=
<<license>>
<<package SOLVEFOR PolynomialSolveByFormulas>>
@
\eject
\begin{thebibliography}{99}
\bibitem{1} nothing
\end{thebibliography}
\end{document}
|
