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Quelle zeruni.gi
Sprache: unbekannt
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#############################################################################
##
## R = Q[w,x,y,z,t,...]
## P = R[p]
##
## g in P hat die Form g = g_0 + g_1 p + ... + g_t p^t
## Einheit: g ist Einheit, falls g_0 Einheit ist
## PDegree: t = PDegree(g)
## PValue : falls g = p^l h mit h_0 <> 0, dann l = PValue(g)
##
## U = {g in R | g Einheit}
## W = Localisation von R bei U = {g/h | g in R, h in U}
##
## g in W hat die Form g = p^l a/b mit a_0 <> 0, b in U
## Einheit: g ist Einheit, falls l = 0 und a Einheit
## PDegree: PDegree(g) = l + PDegree(a) - PDegree(b)
## PValue : PValue(g) = l
##
#############################################################################
##
## Zeros
##
BindGlobal( "ReduceCoeffsByZeros", function( zeros, elm )
local p, a, c, b;
if elm = 0*elm then return elm; fi;
p := IndeterminateByName("p");
a := NumeratorOfRationalFunction(elm);
c := PolynomialCoefficientsOfPolynomial(a, p);
c := List(c, x -> RedPol(zeros,x));
a := Sum(List([1..Length(c)], x -> c[x]*p^(x-1)));
b := DenominatorOfRationalFunction(elm);
c := PolynomialCoefficientsOfPolynomial(b, p);
c := List(c, x -> RedPol(zeros,x));
b := Sum(List([1..Length(c)], x -> c[x]*p^(x-1)));
return a/b;
end );
#############################################################################
##
## Units
##
BindGlobal( "ReduceByUnits", function( units, elm )
local w, U, u, t, f;
# the denominator is always a unit
elm := NumeratorOfRationalFunction(elm);
# set up
w := IndeterminateByName("w");
U := Concatenation(units, [w]);
Append(U, List(VarsOfPoly(elm), x -> x^2-w));
# loop
for u in U do
t := true;
while t = true do
t := false;
f := elm/u;
if IsPolynomial(f) then elm := f; t := true; fi;
od;
od;
return elm;
end );
BindGlobal( "IsLiePUnit", function( uni, elm )
local a, b;
if elm = 0*elm then return false; fi;
if IsRat(elm) then return true; fi;
if PDegree(elm)<>0 then return false; fi;
a := NumeratorOfRationalFunction(elm);
return IsCRF(ReduceByUnits(uni, a));
end );
BindGlobal( "LeadingUnit", function( elm )
local p;
if elm = 0*elm then return elm; fi;
p := IndeterminateByName("p");
return elm / p^PValue(elm);
end );
#############################################################################
##
## Expand input to a system of units and zeros
## Returns either [U,Z] or fail if an inconsistency is detected
##
BindGlobal( "SetupUZSystem", function( pp, U, Z )
local done, zz, uu, x, y, z, w;
# set up
x := IndeterminateByName("x");
y := IndeterminateByName("y");
z := IndeterminateByName("z");
w := IndeterminateByName("w");
# Groebner basis for Z
if Length(Z)>0 then
Z := SquareFreeGB(Z);
if Length(Z) = 1 and (IsInt(Z[1]) or IsCRF(Z[1])) then return fail; fi;
if w-1 in Z or -(w-1) in Z then return fail; fi;
if w-x^2 in Z or -w+x^2 in Z then return fail; fi;
if w-y^2 in Z or -w+y^2 in Z then return fail; fi;
if w-z^2 in Z or -w+z^2 in Z then return fail; fi;
if w^3-x^2 in Z or -w^3+x^2 in Z then return fail; fi;
if w^3-y^2 in Z or -w^3+y^2 in Z then return fail; fi;
if w^3-z^2 in Z or -w^3+z^2 in Z then return fail; fi;
if w*x^2-1 in Z then return fail; fi;
if w*y^2-1 in Z then return fail; fi;
if w*z^2-1 in Z then return fail; fi;
if w^3-1/9*x^2 in Z then return fail; fi;
if 9*w^3-x^2 in Z then return fail; fi;
if w*z^2-y^2 in Z then return fail; fi;
fi;
# reduction for U
U := List(U, x -> RedPol(Z, x));
if ForAny(U, x -> x = 0*x) then return fail; fi;
U := Unique(Concatenation(List(U, x -> SQParts(pp,x))));
U := Filtered(U, x -> not IsCRF(x));
U := List(U, x -> x / LeadingCoefficient(x));
U := Filtered(U, x -> x <> w);
# now return result
return [U,Z];
end );
#############################################################################
##
## Create units and zeros
##
BindGlobal( "CreateUnits", function( pp, A, B )
return SetupUZSystem(pp, Unique(Concatenation(A[1],B)), A[2]);
end );
BindGlobal( "CreateZeros", function( pp, A, B )
return SetupUZSystem( pp, A[1], Concatenation(A[2],[Product(B)]) );
end );
[ Dauer der Verarbeitung: 0.20 Sekunden
(vorverarbeitet)
]
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2026-04-02
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