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Dickson polynomial

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In mathematics, the Dickson polynomials, denoted Dn(x,α), form a polynomial sequence introduced by L. E. Dickson (1897). They were rediscovered by Brewer (1961) in his study of Brewer sums and have at times, although rarely, been referred to as Brewer polynomials.

Over the complex numbers, Dickson polynomials are essentially equivalent to Chebyshev polynomials with a change of variable, and, in fact, Dickson polynomials are sometimes called Chebyshev polynomials.

Dickson polynomials are generally studied over finite fields, where they sometimes may not be equivalent to Chebyshev polynomials. One of the main reasons for interest in them is that for fixed α, they give many examples of permutation polynomials; polynomials acting as permutations of finite fields.

Definition

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First kind

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For integer n > 0 and α in a commutative ring R with identity (often chosen to be the finite field Fq = GF(q)) the Dickson polynomials (of the first kind) over R are given by[1]

The first few Dickson polynomials are

They may also be generated by the recurrence relation for n ≥ 2,

with the initial conditions D0(x,α) = 2 and D1(x,α) = x.

The coefficients are given at several places in the OEIS[2][3][4][5] with minute differences for the first two terms.

Second kind

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The Dickson polynomials of the second kind, En(x,α), are defined by

They have not been studied much, and have properties similar to those of Dickson polynomials of the first kind. The first few Dickson polynomials of the second kind are

They may also be generated by the recurrence relation for n ≥ 2,

with the initial conditions E0(x,α) = 1 and E1(x,α) = x.

The coefficients are also given in the OEIS.[6][7]

Properties

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The Dn are the unique monic polynomials satisfying the functional equation

where αFq and u ≠ 0 ∈ Fq2.[8]

They also satisfy a composition rule,[8]

The En also satisfy a functional equation[8]

for y ≠ 0, y2α, with αFq and yFq2.

The Dickson polynomial y = Dn is a solution of the ordinary differential equation

and the Dickson polynomial y = En is a solution of the differential equation

Their ordinary generating functions are

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By the recurrence relation above, Dickson polynomials are Lucas sequences. Specifically, for α = −1, the Dickson polynomials of the first kind are Fibonacci polynomials, and Dickson polynomials of the second kind are Lucas polynomials.

By the composition rule above, when α is idempotent, composition of Dickson polynomials of the first kind is commutative.

  • The Dickson polynomials with parameter α = 0 give monomials.

  • The Dickson polynomials with parameter α = 1 are related to Chebyshev polynomials Tn(x) = cos (n arccos x) of the first kind by[1]

  • Since the Dickson polynomial Dn(x,α) can be defined over rings with additional idempotents, Dn(x,α) is often not related to a Chebyshev polynomial.

Permutation polynomials and Dickson polynomials

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A permutation polynomial (for a given finite field) is one that acts as a permutation of the elements of the finite field.

The Dickson polynomial Dn(x, α) (considered as a function of x with α fixed) is a permutation polynomial for the field with q elements if and only if n is coprime to q2 − 1.[9]

Fried (1970) proved that any integral polynomial that is a permutation polynomial for infinitely many prime fields is a composition of Dickson polynomials and linear polynomials (with rational coefficients). This assertion has become known as Schur's conjecture, although in fact Schur did not make this conjecture. Since Fried's paper contained numerous errors, a corrected account was given by Turnwald (1995), and subsequently Müller (1997) gave a simpler proof along the lines of an argument due to Schur.

Further, Müller (1997) proved that any permutation polynomial over the finite field Fq whose degree is simultaneously coprime to q and less than q1/4 must be a composition of Dickson polynomials and linear polynomials.

Generalization

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Dickson polynomials of both kinds over finite fields can be thought of as initial members of a sequence of generalized Dickson polynomials referred to as Dickson polynomials of the (k + 1)th kind.[10] Specifically, for α ≠ 0 ∈ Fq with q = pe for some prime p and any integers n ≥ 0 and 0 ≤ k < p, the nth Dickson polynomial of the (k + 1)th kind over Fq, denoted by Dn,k(x,α), is defined by[11]

and

Dn,0(x,α) = Dn(x,α) and Dn,1(x,α) = En(x,α), showing that this definition unifies and generalizes the original polynomials of Dickson.

The significant properties of the Dickson polynomials also generalize:[12]

  • Recurrence relation: For n ≥ 2,
with the initial conditions D0,k(x,α) = 2 − k and D1,k(x,α) = x.
  • Functional equation:
where y ≠ 0, y2α.
  • Generating function:

Notes

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  1. ^ a b Lidl & Niederreiter 1983, p. 355
  2. ^ see OEIS A132460
  3. ^ see OEIS A213234
  4. ^ see OEIS A113279
  5. ^ see OEIS A034807, this one without signs but with a lot of references
  6. ^ see OEIS A115139
  7. ^ see OEIS A011973, this one again without signs but with a lot of references
  8. ^ a b c Mullen & Panario 2013, p. 283
  9. ^ Lidl & Niederreiter 1983, p. 356
  10. ^ Wang, Q.; Yucas, J. L. (2012), "Dickson polynomials over finite fields", Finite Fields and Their Applications, 18 (4): 814–831, doi:10.1016/j.ffa.2012.02.001
  11. ^ Mullen & Panario 2013, p. 287
  12. ^ Mullen & Panario 2013, p. 288

References

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