Critical Slow Growth in Averaged Meta-Fibonacci Recursions

Abstract

We introduce a family of averaged meta-Fibonacci recursions Qα,m(n) = 1+ α 1m Σj=1m Qα,m(n-Qα,m(n-j)) , with initial conditions Qα,m(1)=·s=Qα,m(m)=1. Unlike classical Hofstadter-type recursions, the averaging mechanism produces highly regular large-scale behavior. For the critical parameter value α=1, we prove global well-definedness for all m1, establish an exact triangular block structure, and show that the value k occurs exactly k consecutive times. As a consequence, Q1,m(n) 2n. For the supercritical regime α>1, we derive an asymptotic slope constraint showing that any positive linear growth rate, if it exists, must equal 1-α-1. Numerical experiments support the existence of a linear-growth phase and suggest a broader universality phenomenon for generalized averaging operators, including positive-power Lp-means. These results indicate that averaging induces a robust regularization mechanism for self-referential recursive systems, leading to stable slow-growth dynamics and nontrivial phase structure.