The Burgers Transform: From Holomorphic Functions to Rigid Elliptic Structures

Abstract

We introduce the Burgers transform B, a nonlinear bijection between holomorphic functions f U+ and rigid variable elliptic structures on the plane, defined implicitly by λ = f(y-λ x). The output automatically satisfies the conservative complex Burgers equation λx+λλy=0. Our main result is that holomorphicity of the seed f is necessary, not merely sufficient, for rigidity: any C1 function whose implicit solution satisfies λx+λλy=0 must be holomorphic. This closes a gap in the existing literature and identifies Hol(U,C+) as the maximal seed space compatible with rigidity. The obstruction formula H|x=0 = 2i\,(Im f)\,fw quantifies the cost of non-holomorphicity at the level of the initial data. We characterise the domain of B through shock formation, its interaction with affine automorphisms of C+, and the infinitesimal structure: the propagator Pf = DBf satisfies a Jacobian-twisted multiplicativity that deforms the seed algebra by the density of characteristics. Four worked examples -- affine, exponential, inverse, and trigonometric seeds -- show that the complexity class of a seed and that of the resulting structure are generically unrelated.