primitive polynomial

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Primitive polynomial

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Noun

primitive polynomial (plural primitive polynomials)

(algebra, ring theory) A polynomial over an integral domain R such that no noninvertible element of R divides all its coefficients at once; (more specifically) a polynomial over a GCD domain R such that the greatest common divisor of its coefficients equals 1.
- 1992, T. T. Moh, Algebra, World Scientific, page 124:
  We claim that every primitive polynomial can be written as a product of irreducible elements in $\mathbf {D} [x]$ . […] By induction on the degree of the primitive polynomials, we conclude that both $g(x),h(x)$ can be written as product of irreducible elements in $\mathbf {D} [x]$ .
- 2000, David M. Arnold, Abelian Groups and Representations of Finite Partially Ordered Sets, Springer, page 114:
  If $f(x)\in \mathbb {Z} [x]$ , the ring of polynomials with coefficients in $\mathbb {Z}$ , then the content of $f$ , denoted by $c(f)$ , is the greatest common divisor of the coefficients of $f$ . The polynomial $f(x)$ is called a primitive polynomial if $c(f)=1$ . Since $c(fg)=c(f)c(g)$ , by Gauss's lemma [Hungerford, 74], the set $S$ of primitive polynomials in $\mathbb {Z} [x]$ is a multiplicatively closed set. Define $\Lambda =\mathbb {Z} [x]_{S}$ , the localization of $\mathbb {Z} [x]$ at $S$ , a subring of the field of quotients $\mathbb {Q} (x)$ of $\mathbb {Z} [x]$ . Elements of $\Lambda$ are of the form $f(x)/g(x)$ with $f(x),g(x)\in \mathbb {Z} [x]$ and $g(x)$ a primitive polynomial.
- 2000, Jun-ichi Igusa, An Introduction to the Theory of Local Zeta Functions, American Mathematical Society, page 1:
  According to the Gauss lemma, the product of primitive polynomials is primitive. Therefore if $f(x),g(x)$ are primitive and $f(x)=g(x)h(x)$ with $h(x)$ in $F[x]$ , then necessarily $h(x)$ is in $A[x]$ and primitive. […] The irreducible elements of $A[x]$ are irreducible elements of $A$ and primitive polynomials which are irreducible in $F[x]$ .
(algebra, field theory) A polynomial over a given finite field whose roots are primitive elements; especially, the minimal polynomial of a primitive element of said finite field.
- 2002, Charles E. Stroud, A Designer's Guide to Built-in Self-Test, Kluwer Academic, page 69:
  Primitive polynomials make the initialization of LFSRs a simpler task since any nonzero state guarantees that all non-zero states will be visited in the maximum length sequence.
- 2003, Zhe-Xian Wan, Lectures on Finite Fields and Galois Rings, World Scientific, page 145:
  Definition 7.2 Let $f(x)$ be a monic polynomial of degree $n$ over $\mathbb {F} _{q}$ . If $f(x)$ has a primitive element of $\mathbb {F} _{q^{n}}$ as one of its roots, $f(x)$ is called a primitive polynomial of degree $n$ over $\mathbb {F} _{q}$ .
  Theorem 7.7 For any positive integer $n$ there always exist primitive polynomials of degree $n$ over $\mathbb {F} _{q}$ . All the $n$ roots of a primitive polynomial of degree $n$ over $\mathbb {F} _{q}$ are primitive elements of $\mathbb {F} _{q^{n}}$ . All primitive polynomials of degree $n$ over $\mathbb {F} _{q}$ are irreducible over $\mathbb {F} _{q}$ . The number of primitive polynomials of degree $n$ over $\mathbb {F} _{q}$ is equal to $\phi (q^{n}-1)/n$ .
- 2008, Stephen D. Cohen, Mateja Preŝern, “The Hansen-Mullen Primitivity Conjecture: Completion of Proof”, in James McKee, Chris Smyth, editors, Number Theory and Polynomials, Cambridge University Press, page 89:
  This paper completes an efficient proof of the Hansen-Mullen Primitivity Conjecture (HMPC) when n = 5, 6, 7 or 8. The HMPC (1992) asserts that, with some (mostly obvious) exceptions, there exists a primitive polynomial of degree n over any finite field with any coefficient arbitrarily prescribed.

Usage notes

Since fields are rings, the domain of applicability of the ring theory definition includes that of the one specific to Galois fields. It is thus perfectly feasible for a given instance to be a primitive polynomial in both senses of the term: such is the case, for example, for the minimal polynomial (over a given finite field) of a primitive element (i.e., that has said primitive element as root).
(polynomial over a finite field whose roots are primitive elements):
- More precisely, a primitive polynomial over (with coefficients in) $\mathbb {F} _{q}$ of order $n$ has roots that are primitive elements of $\mathbb {F} _{q^{n}}$ .
- Given a primitive element $\alpha \in \mathbb {F} _{q}$ $\alpha \in \mathbb {F} _{q}$ , the set of powers $\{1,\alpha ,\dots \alpha ^{n-1}\}$ $\{1,\alpha ,\dots \alpha ^{n-1}\}$ constitutes a polynomial basis of $\mathbb {F} _{q^{n}}$ $\mathbb {F} _{q^{n}}$ .
  - In consequence, a primitive polynomial is sometimes defined as a polynomial that generates $\mathbb {F} _{q^{n}}$ .

Hyponyms

(polynomial over an integral domain such that no noninvertible element divides all of its coefficients): monic polynomial

Related terms

primitive part (of a polynomial)

Translations

polynomial over an integral domain such that no noninvertible element divides all of its coefficients

polynomial over a finite field whose roots are primitive elements