Finite free perpetuities

Abstract

We introduce and study finite free perpetuities, defined as monic polynomial solutions of degree n to the affine fixed-point equation \[ p(z) = E\![ An\,p\!(z-BA)1\A≠0\ ] + E\![ (z-B)n1\A=0\ ], \] where A and B are complex-valued random variables with finite moments up to order n. Equivalently, if p(z)=E[(z-X)n], then p encodes a truncated moment version of the classical perpetuity equation Xd=AX+B with X and (A,B) independent. This places finite free perpetuities between classical perpetuities and free-probabilistic fixed-point laws. We prove existence and uniqueness under weak conditions, and we identify a broad class of admissible pairs (A,B) for which the resulting polynomial has only real, nonnegative zeros. Our approach uses finite free additive and multiplicative convolutions together with a probabilistic representation via the U-transform. As a motivating example, we exhibit an explicit family of finite free perpetuities expressed in terms of Jacobi polynomials and show that their empirical root distributions converge to a free-beta-prime law. More generally, for admissible sequences of parameters, we prove weak convergence of the empirical root distributions of finite free perpetuities to the law of a free perpetuity characterized by the corresponding free fixed-point equation. This yields a finite-degree polynomial model approximating free perpetuities and clarifies the connection between classical affine recursions, finite free convolutions, and free probability.