Parameterizing and inverting analytic mappings with unit Jacobian

Abstract

Let x=(x1,…,xn)∈ Cn be a vector of complex variables, denote by A=(ajk) a square matrix of size n≥ 2, and let ∈O() be an analytic function defined in a nonempty domain ⊂ C. We investigate the family of mappings f=(f1,…,fn): Cn→ Cn, f[A,](x):=x+(Ax) with the coordinates fj : x xj + (Σk=1n ajkxk), j=1,…,n whose Jacobian is identically equal to a nonzero constant for any x such that all of fj are well-defined. Let U be a square matrix such that the Jacobian of the mapping f[U,](x) is a nonzero constant for any x and moreover for any analytic function ∈O(). We show that any such matrix U is uniquely defined, up to a suitable permutation similarity of matrices, by a partition of the dimension n into a sum of m positive integers together with a permutation on m elements. For any d=2,3,… we construct n-parametric family of square matrices H(s), s∈ Cn such that for any matrix U as above the mapping x+((U H(s))x)d defined by the Hadamard product U H(s) has unit Jacobian. We prove any such mapping to be polynomially invertible and provide an explicit recursive formula for its inverse.