The Collatz Conjecture remains one of the most enduring unsolved problems in mathematics, despite being based on an extraordinarily simple rule. Given any natural number \ (n \), the conjecture posits that repeatedly applying the operation—dividing by 2 if even, or multiplying by 3 and adding 1 if odd—will eventually result in the number 1. This paper develops a structural perspective by proposing the Collatz Tree as a framework to organize and visualize natural numbers. Each branch is the geometric ray \ (\k 2ᵇ\₁ ₀ \) for an odd odd core \ (k \), and the trunk is the ray from 1. We introduce a trunk—branch indexing that bijects \ (N \) with \ (Z ₀×Z ₀ \). Algebraically, we encode Collatz steps as affine maps and prove absence of nontrivial finite cycles for a three-way map \ (T \) ; via a bridge, this implies the same for the standard accelerated map \ (A (n) = (3n+1) /2^v2 (3n+1) \) on odd integers. Thus the global Collatz convergence reduces to an independent pillar: coverage (reachability) of the inverse tree rooted at 1, isolating cycle-freeness from coverage and reducing the conjecture to the remaining reachability pillar. Prior work (e. g. , Kosobutskyy) studied reverse-oriented trees via Jacobsthal sequences, emphasizing periodic and statistical aspects. Our approach differs in both formulation and aim: we build a tree rooted at 1 and give a constructive, graph-theoretic route toward cycle-freeness and reduction to coverage.
Kazuhito Owada (Wed,) studied this question.
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