Faugère's F4 and F5 algorithms

On this page

In computer algebra, the Faugère F4 algorithm, by Jean-Charles Faugère, computes the Gröbner basis of an ideal of a multivariate polynomial ring. The algorithm uses the same mathematical principles as the Buchberger algorithm, but computes many normal forms in one go by forming a generally sparse matrix and using fast linear algebra to do the reductions in parallel.

The Faugère F5 algorithm first calculates the Gröbner basis of a pair of generator polynomials of the ideal. Then it uses this basis to reduce the size of the initial matrices of generators for the next larger basis:

If Gprev is an already computed Gröbner basis (f2, …, fm) and we want to compute a Gröbner basis of (f1) + Gprev then we will construct matrices whose rows are m f1 such that m is a monomial not divisible by the leading term of an element of Gprev.

This strategy allows the algorithm to apply two new criteria based on what Faugère calls signatures of polynomials. Thanks to these criteria, the algorithm can compute Gröbner bases for a large class of interesting polynomial systems, called regular sequences, without ever simplifying a single polynomial to zero—the most time-consuming operation in algorithms that compute Gröbner bases. It is also very effective for a large number of non-regular sequences.

We don't have any images related to Faugère's F4 and F5 algorithms yet.

You can add one yourself here.

We don't have any YouTube videos related to Faugère's F4 and F5 algorithms yet.

You can add one yourself here.

We don't have any PDF documents related to Faugère's F4 and F5 algorithms yet.

You can add one yourself here.

We don't have any Books related to Faugère's F4 and F5 algorithms yet.

You can add one yourself here.

We don't have any archived web articles related to Faugère's F4 and F5 algorithms yet.

You can submit a link to a page to archive here.

Implementations

The Faugère F4 algorithm is implemented

in FGb, Faugère's own implementation, which includes interfaces for using it from C/C++ or Maple,
in Maple computer algebra system, as the option method=fgb of function Groebner[gbasis]
in the Magma computer algebra system,
in the SageMath computer algebra system,

Study versions of the Faugère F5 algorithm is implemented in

the SINGULAR computer algebra system;¹
the SageMath computer algebra system.
in SymPy Python package.²

Applications

The previously intractable "cyclic 10" problem was solved by F5, as were a number of systems related to cryptography; for example HFE and C*.

Faugère, J.-C. (June 1999). "A new efficient algorithm for computing Gröbner bases (F4)" (PDF). Journal of Pure and Applied Algebra. 139 (1): 61–88. doi:10.1016/S0022-4049(99)00005-5. ISSN 0022-4049.
Faugère, J.-C. (July 2002). "A new efficient algorithm for computing Gröbner bases without reduction to zero ( F 5 )". Proceedings of the 2002 international symposium on Symbolic and algebraic computation (PDF). ACM Press. pp. 75–83. CiteSeerX 10.1.1.188.651. doi:10.1145/780506.780516. ISBN 978-1-58113-484-1. S2CID 15833106.
Till Stegers Faugère's F5 Algorithm Revisited (alternative link). Diplom-Mathematiker Thesis, advisor Johannes Buchmann, Technische Universität Darmstadt, September 2005 (revised April 27, 2007). Many references, including links to available implementations.

External links

Faugère's home page (includes pdf reprints of additional papers)
An introduction to the F4 algorithm.

References

Eder, Christian (2008). "On The Criteria Of The F5 Algorithm". arXiv:0804.2033 [math.AC]. /wiki/ArXiv_(identifier) ↩
"Internals of the Polynomial Manipulation Module — SymPy 1.9 documentation". https://docs.sympy.org/latest/modules/polys/internals.html#groebner-basis-algorithms ↩