Top
Back: is_nested
Forward: chinrempoly
FastBack:
FastForward:
Up: Singular Manual
Top: Singular Manual
Contents: Table of Contents
Index: Index
About: About this document

D.4.22 nfmodstd_lib

Library:
nfmodstd.lib
Purpose:
Groebner bases of ideals in polynomial rings over algebraic number fields
Authors:
D.K. Boku [email protected]
W. Decker [email protected]
C. Fieker [email protected]

Overview:
A library for computing the Groebner basis of an ideal in the polynomial ring over an algebraic number field Q(t) using the modular methods, where t is algebraic over the field of rational numbers Q. For the case Q(t) = Q, the procedure is inspired by Arnold [1]. This idea is then extended to the case t not in Q using factorization as follows:
Let f be the minimal polynomial of t.
For I, I' ideals in Q(t)[X], Q[X,t]/<f> respectively, we map I to I' via the map sending t to t + <f>. We first choose a prime p such that f has at least two factors in characteristic p and add each factor f_i to I' to obtain the ideal J'_i = I' + <f_i>. We then compute a standard basis G'_i of J'_i for each i and combine the G'_i to G_p (a standard basis of I'_p) using chinese remaindering for polynomials. The procedure is repeated for many primes p, where we compute the G_p in parallel until the number of primes is sufficiently large to recover the correct standard basis G' of I'. Finally, by mapping G' back to Q(t)[X], a standard basis G of I is obtained.
The procedure also works if the input is a module. For this, we consider the rings A = Q(t)[X] and A' = (Q[t]/<f>)[X]. For submodules I, I' in A^m, A'^m, respectively, we map I to I' via the map sending t to t + <f>. As above, we first choose a prime p such that f has at least two factors in characteristic p. For each factor f_{i,p} of f_p := (f mod p), we set I'_{i,p} := (I'_p mod f_{i,p}). We then compute a standard basis G'_i of I'_{i,p} over F_p[t]/<f_{i,p}> for each i and combine the G'_i to G_p (a standard basis of I'_p) using chinese remaindering for polynomials. The procedure is repeated for many primes p as described above and we finally obtain a standard basis of I.

References:
[1] E. A. Arnold: Modular algorithms for computing Groebner bases. J. Symb. Comp. 35, 403-419 (2003).

Procedures:

D.4.22.1 chinrempoly  chinese remaindering for polynomials
D.4.22.2 nfmodStd  standard basis of I over algebraic number field using modular methods


Top Back: is_nested Forward: chinrempoly FastBack: FastForward: Up: Singular Manual Top: Singular Manual Contents: Table of Contents Index: Index About: About this document
            User manual for Singular version 4.3.2, 2023, generated by texi2html.