Jump to content

Berlekamp–Rabin algorithm: Difference between revisions

From Wikipedia, the free encyclopedia
Content deleted Content added
m spacing
Line 13: Line 13:


=== Randomization ===
=== Randomization ===
Let <math display="inline">f(x) = (x-\lambda_1)(x-\lambda_2)\cdots(x-\lambda_n)</math>. Finding all roots of this polynomial is equivalent to finding its factorization into linear factors. To find such factorization it is sufficient to split the polynomial into any two non-trivial divisors and factorize them recursively. To do this, consider the polynomial <math display="inline">f_z(x)=f(x-z) = (x-\lambda_1 - z)(x-\lambda_2 - z) \cdots (x-\lambda_n-z)</math> where <math>z</math> is some any element of <math>\mathbb F_p</math>. If one can represent this polynomial as the product <math>f_z(x)=p_0(x)p_1(x)</math> then in terms of the initial polynomial it means that <math>f(x) =p_0(x+z)p_1(x+z)</math>, which provides needed factorization of <math>f(x)</math>.<ref name=":0" /><ref name=":2" />
Let <math display="inline">f(x) = (x-\lambda_1)(x-\lambda_2)\cdots(x-\lambda_n)</math>. Finding all roots of this polynomial is equivalent to finding its factorization into linear factors. To find such factorization it is sufficient to split the polynomial into any two non-trivial divisors and factorize them recursively. To do this, consider the polynomial <math display="inline">f_z(x)=f(x-z) = (x-\lambda_1 - z)(x-\lambda_2 - z) \cdots (x-\lambda_n-z)</math> where <math>z</math> is some element of <math>\mathbb F_p</math>. If one can represent this polynomial as the product <math>f_z(x)=p_0(x)p_1(x)</math> then in terms of the initial polynomial it means that <math>f(x) =p_0(x+z)p_1(x+z)</math>, which provides needed factorization of <math>f(x)</math>.<ref name=":0" /><ref name=":2" />


=== Classification of <math>\mathbb F_p</math> elements ===
=== Classification of <math>\mathbb F_p</math> elements ===

Revision as of 01:29, 12 August 2024

Elwyn R. Berlekamp at conference on Combinatorial Game Theory at Banff International Research Station Elwyn Berlekamp

In number theory, Berlekamp's root finding algorithm, also called the Berlekamp–Rabin algorithm, is the probabilistic method of finding roots of polynomials over the field with elements. The method was discovered by Elwyn Berlekamp in 1970[1] as an auxiliary to the algorithm for polynomial factorization over finite fields. The algorithm was later modified by Rabin for arbitrary finite fields in 1979.[2] The method was also independently discovered before Berlekamp by other researchers.[3]

History

The method was proposed by Elwyn Berlekamp in his 1970 work[1] on polynomial factorization over finite fields. His original work lacked a formal correctness proof[2] and was later refined and modified for arbitrary finite fields by Michael Rabin.[2] In 1986 René Peralta proposed a similar algorithm[4] for finding square roots in .[5] In 2000 Peralta's method was generalized for cubic equations.[6]

Statement of problem

Let be an odd prime number. Consider the polynomial over the field of remainders modulo . The algorithm should find all in such that in .[2][7]

Algorithm

Randomization

Let . Finding all roots of this polynomial is equivalent to finding its factorization into linear factors. To find such factorization it is sufficient to split the polynomial into any two non-trivial divisors and factorize them recursively. To do this, consider the polynomial where  is some element of . If one can represent this polynomial as the product then in terms of the initial polynomial it means that , which provides needed factorization of .[1][7]

Classification of elements

Due to Euler's criterion, for every monomial exactly one of following properties holds:[1]

  1. The monomial is equal to if ,
  2. The monomial divides if  is quadratic residue modulo ,
  3. The monomial divides if  is quadratic non-residual modulo .

Thus if is not divisible by , which may be checked separately, then is equal to the product of greatest common divisors and .[7]

Berlekamp's method

The property above leads to the following algorithm:[1]

  1. Explicitly calculate coefficients of ,
  2. Calculate remainders of modulo by squaring the current polynomial and taking remainder modulo ,
  3. Using exponentiation by squaring and polynomials calculated on the previous steps calculate the remainder of modulo ,
  4. If then mentioned below provide a non-trivial factorization of ,
  5. Otherwise all roots of are either residues or non-residues simultaneously and one has to choose another .

If is divisible by some non-linear primitive polynomial over then when calculating with and one will obtain a non-trivial factorization of , thus algorithm allows to find all roots of arbitrary polynomials over .

Modular square root

Consider equation having elements and as its roots. Solution of this equation is equivalent to factorization of polynomial over . In this particular case problem it is sufficient to calculate only . For this polynomial exactly one of the following properties will hold:

  1. GCD is equal to which means that and are both quadratic non-residues,
  2. GCD is equal to which means that both numbers are quadratic residues,
  3. GCD is equal to which means that exactly one of these numbers is quadratic residue.

In the third case GCD is equal to either or . It allows to write the solution as .[1]

Example

Assume we need to solve the equation . For this we need to factorize . Consider some possible values of :

  1. Let . Then , thus . Both numbers are quadratic non-residues, so we need to take some other .
  1. Let . Then , thus . From this follows , so and .

A manual check shows that, indeed, and .

Correctness proof

The algorithm finds factorization of in all cases except for ones when all numbers are quadratic residues or non-residues simultaneously. According to theory of cyclotomy,[8] the probability of such an event for the case when are all residues or non-residues simultaneously (that is, when would fail) may be estimated as where  is the number of distinct values in .[1] In this way even for the worst case of and , the probability of error may be estimated as and for modular square root case error probability is at most .

Complexity

Let a polynomial have degree . We derive the algorithm's complexity as follows:

  1. Due to the binomial theorem , we may transition from to in time.
  2. Polynomial multiplication and taking remainder of one polynomial modulo another one may be done in , thus calculation of is done in .
  3. Binary exponentiation works in .
  4. Taking the of two polynomials via Euclidean algorithm works in .

Thus the whole procedure may be done in . Using the fast Fourier transform and Half-GCD algorithm,[9] the algorithm's complexity may be improved to . For the modular square root case, the degree is , thus the whole complexity of algorithm in such case is bounded by per iteration.[7]

References

  1. ^ a b c d e f g Berlekamp, E. R. (1970). "Factoring polynomials over large finite fields". Mathematics of Computation. 24 (111): 713–735. doi:10.1090/S0025-5718-1970-0276200-X. ISSN 0025-5718.
  2. ^ a b c d M. Rabin (1980). "Probabilistic Algorithms in Finite Fields". SIAM Journal on Computing. 9 (2): 273–280. CiteSeerX 10.1.1.17.5653. doi:10.1137/0209024. ISSN 0097-5397.
  3. ^ Donald E Knuth (1998). The art of computer programming. Vol. 2 Vol. 2. ISBN 978-0201896848. OCLC 900627019.
  4. ^ Tsz-Wo Sze (2011). "On taking square roots without quadratic nonresidues over finite fields". Mathematics of Computation. 80 (275): 1797–1811. arXiv:0812.2591. doi:10.1090/s0025-5718-2011-02419-1. ISSN 0025-5718. S2CID 10249895.
  5. ^ R. Peralta (November 1986). "A simple and fast probabilistic algorithm for computing square roots modulo a prime number (Corresp.)". IEEE Transactions on Information Theory. 32 (6): 846–847. doi:10.1109/TIT.1986.1057236. ISSN 0018-9448.
  6. ^ C Padró, G Sáez (August 2002). "Taking cube roots in Zm". Applied Mathematics Letters. 15 (6): 703–708. doi:10.1016/s0893-9659(02)00031-9. ISSN 0893-9659.
  7. ^ a b c d Alfred J. Menezes, Ian F. Blake, XuHong Gao, Ronald C. Mullin, Scott A. Vanstone (1993). Applications of Finite Fields. The Springer International Series in Engineering and Computer Science. Springer US. ISBN 9780792392828.{{cite book}}: CS1 maint: multiple names: authors list (link)
  8. ^ Marshall Hall (1998). Combinatorial Theory. John Wiley & Sons. ISBN 9780471315186.
  9. ^ Aho, Alfred V. (1974). The design and analysis of computer algorithms. Addison-Wesley Pub. Co. ISBN 0201000296.