quasiregularity

Quasiregularity is a concept in geometric function theory that describes a class of mappings between domains in Euclidean space that generalize holomorphic functions to higher dimensions by allowing controlled distortion. In its standard form, a mapping f: U → R^n, with U open in R^n and n ≥ 2, is called K-quasiregular if f belongs to the Sobolev space W^{1,n}_{loc}(U, R^n), is sense-preserving, and there exists a constant K ≥ 1 such that the distortion of the differential is bounded almost everywhere. Concretely, the derivative Df has operator norm |Df(x)| and the Jacobian determinant J_f(x) = det Df(x); the inequality |Df(x)|^n ≤ K J_f(x) holds for almost every x in U (equivalently, the local stretching is bounded by K times the local volume expansion). Quasiregular mappings are also known to be discrete and open, and non-constant quasiregular maps have finite multiplicity.

Quasiregularity generalizes conformality: in two dimensions, holomorphic and anti-holomorphic maps are quasiregular, and conformal maps are

Key properties include local Hölder continuity, openness and discreteness, and a rich regularity theory. Quasiregular maps