English

Study of Meta-Fibonacci Integer Sequences by Continuous Self-Referential Functional Equations

Statistical Mechanics 2026-03-19 v1 Dynamical Systems Chaotic Dynamics

Abstract

I propose and investigate the use of continuous functional equations for the study of meta-Fibonacci integer sequences. This exploratory study includes three sequences with quite different behavior: Conway's famous sequence A(n)=A(A(n1))+A(nA(n1))A(n)= A(A(n-1))+A(n-A(n-1)), the sequence D(n)=D(D(n1))+D(n1D(n2))D(n)= D(D(n-1))+D(n-1-D(n-2)) introduced by the present author more than 25 years ago, and Hofstadter's well-known Q(n)=Q(nQ(n1))+Q(nQ(n2))Q(n)= Q(n-Q(n-1))+Q(n-Q(n-2)). The sequences are studied in their equivalent detrended forms (a,d,q)(n)=2(A,D,Q)(n)n(a,d,q)(n)=2\,(A,D,Q)(n)-n. For a(n)a(n) and d(n)d(n), a highly symmetric functional equation admits exact continuous solutions that nicely model the global behavior (backbone) of the sequences. For the Hofstadter sequence, a continuous functional model is developed that leads to a random matrix approach for the generation and study of fractal solutions. Two remarkable properties of the Q-sequence are reproduced by the model: the anomalous scaling of the generation length, which scales (2η)k\sim (2-\eta)^k, and the anomalous amplitude growth that scales like 2αk2^{\alpha k}.

Cite

@article{arxiv.2603.17509,
  title  = {Study of Meta-Fibonacci Integer Sequences by Continuous Self-Referential Functional Equations},
  author = {Klaus Pinn},
  journal= {arXiv preprint arXiv:2603.17509},
  year   = {2026}
}

Comments

24 pages, 8 figures

R2 v1 2026-07-01T11:25:47.481Z