In computational number theory, Evdokimov's algorithm, named after Sergei Evdokimov, is an algorithm for factorization of polynomials over finite fields. It was the fastest algorithm known for this problem, from its publication in 1994 until 2020.[1] It can factorize a one-variable polynomial of degree over an explicitly given finite field of cardinality . Assuming the generalized Riemann hypothesis the algorithm runs in deterministic time [2] (see Big O notation). This is an improvement of both Berlekamp's algorithm and Rónyai's algorithm[3] in the sense that the first algorithm is polynomial for small characteristic of the field, whearas the second one is polynomial for small ; however, both of them are exponential if no restriction is made.
The factorization of a polynomial over a ground field is reduced to the case when has no multiple roots and is completely splitting over (i.e. has distinct roots in ). In order to find a root of in this case, the algorithm deals with polynomials not only over the ground field but also over a completely splitting semisimple algebra over (an example of such an algebra is given by , where ). The main problem here is to find efficiently a nonzero zero-divisor in the algebra. The GRH is used only to take roots in finite fields in polynomial time. Thus the Evdokimov algorithm, in fact, solves a polynomial equation over a finite field "by radicals" in quasipolynomial time.
The analyses of Evdokimov's algorithm is closely related with some problems in the association scheme theory. With the help of this approach, it was proved [4] that if is a prime and has a ‘large’ -smooth divisor , then a modification of the Evdokimov algorithm finds a nontrivial factor of the polynomial in deterministic time, assuming GRH and that .
References
edit- ^ Guo, Zeyu (2020), "Factoring polynomials over finite fields with linear Galois groups: an additive combinatorics approach", in Esparza, Javier; Král', Daniel (eds.), 45th International Symposium on Mathematical Foundations of Computer Science, MFCS 2020, August 24-28, 2020, Prague, Czech Republic, LIPIcs, vol. 170, Schloss Dagstuhl - Leibniz-Zentrum für Informatik, pp. 42:1–42:14, arXiv:2007.00512, doi:10.4230/LIPICS.MFCS.2020.42
- ^ Evdokimov, Sergei (1994), "Factorization of polynomials over finite fields in subexponential time under GRH", Algorithmic Number Theory, Lecture Notes in Computer Science, vol. 877, pp. 209–219, doi:10.1007/3-540-58691-1_58, ISBN 978-3-540-58691-3
- ^ Rónyai, Lajos (1988), "Factoring polynomials over finite fields", Journal of Algorithms, 9 (3): 391–400, doi:10.1016/0196-6774(88)90029-6, S2CID 16360930
- ^ Arora, Manuel; Ivanyos, Gabor; Karpinski, Marek; Saxena, Nitin (2014), "Deterministic polynomial factoring and association schemes", LMS Journal of Computation and Mathematics, 17: 123–140, arXiv:1205.5653, doi:10.1112/S1461157013000296, S2CID 31522031
Further reading
edit- Shparlinski, I. (1999). Finite Fields: Theory and Computation. The Meeting Point of Number Theory, Computer Science, Coding Theory and Cryptography. Mathematics and Its Applications. Vol. 477. Springer Verlag.