On Linear Representation, Complexity and Inversion of maps over finite fields

Abstract

This paper defines a linear representation for nonlinear maps F:Fn→Fn where F is a finite field, in terms of matrices over F. This linear representation of the map F associates a unique number N and a unique matrix M in FN× N, called the Linear Complexity and the Linear Representation of F respectively, and shows that the compositional powers F(k) are represented by matrix powers Mk. It is shown that for a permutation map F with representation M, the inverse map has the linear representation M-1. This framework of representation is extended to a parameterized family of maps Fλ(x): F F, defined in terms of a parameter λ ∈ F, leading to the definition of an analogous linear complexity of the map Fλ(x), and a parameter-dependent matrix representation Mλ defined over the univariate polynomial ring F[λ]. Such a representation leads to the construction of a parametric inverse of such maps where the condition for invertibility is expressed through the unimodularity of this matrix representation Mλ. Apart from computing the compositional inverses of permutation polynomials, this linear representation is also used to compute the cycle structures of the permutation map. Lastly, this representation is extended to a representation of the cyclic group generated by a permutation map F, and to the group generated by a finite number of permutation maps over F.