Contents Menu Expand Light mode Dark mode Auto light/dark, in light mode Auto light/dark, in dark mode Skip to content
Polynomials
Light Logo Dark Logo
Version 10.6 Reference Manual
  • Home - Polynomials
  • Constructors for polynomial rings
  • Univariate Polynomials and Polynomial Rings
    • Univariate Polynomial Rings
    • Ring homomorphisms from a polynomial ring to another ring
    • Univariate polynomial base class
    • Univariate Polynomials over domains and fields
    • Univariate Polynomials over GF(2) via NTL’s GF2X
    • Univariate polynomials over number fields
    • Dense univariate polynomials over \(\ZZ\), implemented using FLINT
    • Dense univariate polynomials over \(\ZZ\), implemented using NTL.
    • Univariate polynomials over \(\QQ\) implemented via FLINT
    • Dense univariate polynomials over \(\ZZ/n\ZZ\), implemented using FLINT
    • Dense univariate polynomials over \(\ZZ/n\ZZ\), implemented using NTL
    • Dense univariate polynomials over \(\RR\), implemented using MPFR
    • Polynomial Interfaces to Singular
    • Base class for generic \(p\)-adic polynomials
    • \(p\)-adic Capped Relative Dense Polynomials
    • \(p\)-adic Flat Polynomials
    • Univariate Polynomials over GF(p^e) via NTL’s ZZ_pEX
    • Isolate Real Roots of Real Polynomials
    • Isolate Complex Roots of Polynomials
    • Refine polynomial roots using Newton–Raphson
    • Ideals in Univariate Polynomial Rings
    • Quotients of Univariate Polynomial Rings
    • Elements of Quotients of Univariate Polynomial Rings
    • Polynomial Compilers
    • Polynomial multiplication by Kronecker substitution
    • Integer-valued polynomial rings
    • Quantum-valued polynomial rings
  • Generic Convolution
  • Fast calculation of cyclotomic polynomials
  • Multivariate Polynomials and Polynomial Rings
    • Term orders
    • Base class for multivariate polynomial rings
    • Base class for elements of multivariate polynomial rings
    • Multivariate Polynomial Rings over Generic Rings
    • Generic Multivariate Polynomials
    • Ideals in multivariate polynomial rings
    • Polynomial Sequences
    • Multivariate Polynomials via libSINGULAR
    • Direct low-level access to SINGULAR’s Groebner basis engine via libSINGULAR
    • Solution of polynomial systems using msolve
    • Generic data structures for multivariate polynomials
    • Compute Hilbert series of monomial ideals
    • Class to flatten polynomial rings over polynomial ring
    • Monomials
  • Classical Invariant Theory
    • Classical Invariant Theory
    • Reconstruction of Algebraic Forms
  • Educational Versions of Groebner Basis Related Algorithms
    • Educational versions of Groebner basis algorithms
    • Educational versions of Groebner basis algorithms: triangular factorization
    • Educational version of the \(d\)-Groebner basis algorithm over PIDs
  • Fraction Field of Integral Domains
  • Fraction Field Elements
  • Univariate rational functions over prime fields
  • Ring of Laurent Polynomials (base class)
  • Ring of Laurent Polynomials
  • Elements of Laurent polynomial rings
  • MacMahon’s Partition Analysis Omega Operator
  • Infinite Polynomial Rings
  • Elements of Infinite Polynomial Rings
  • Symmetric Ideals of Infinite Polynomial Rings
  • Symmetric Reduction of Infinite Polynomials
  • Univariate Tropical Polynomials
  • Multivariate Tropical Polynomials
  • Tropical Varieties
  • Boolean Polynomials
Back to top
View this page
Edit this page

\(p\)-adic Flat Polynomials¶

class sage.rings.polynomial.padics.polynomial_padic_flat.Polynomial_padic_flat(parent, x=None, check=True, is_gen=False, construct=False, absprec=None)[source]¶

Bases: Polynomial_generic_dense, Polynomial_padic

Next
Univariate Polynomials over GF(p^e) via NTL’s ZZ_pEX
Previous
\(p\)-adic Capped Relative Dense Polynomials
Copyright © 2005--2025, The Sage Development Team
Made with Sphinx and @pradyunsg's Furo
On this page
  • \(p\)-adic Flat Polynomials
    • Polynomial_padic_flat