The Collatz function as an automorphic Cayley colour graph:decidability of an+b conjectures, proof of the 3n + 1 conjecture

Abstract

The Collatz conjecture states that repeated steps of n 3n+1 at odd numbers and n n/2 at even numbers amount to walks over root paths to the branching number c=4 in the `trivial' cyclic root 4 2 1 4 … of one connected Collatz graph. The Collatz graph with reverse arrows n 2n and n (n-1)/3 can be transformed to a 3-regular automorphic Cayley color graph T 0 with as nodes the branching numbers with a remainder of 4 or 16 when divided by 18, building the congruence classes [4,16]18. Labeling the 2k breadth-first ordered root paths with 2k binary numbers on the binary number line, for k=1,2,3,…, and pairing them with the 2k output numbers of these root paths, gives 2k paired numbers. The 3-regular Cayley graph of these paired branching numbers can be transformed to a 4-regular Middle Pages graph. This 4-regular graph offers to all paired branching numbers from the congruence classes [4,16]18 a unique Eulerian tour to and from the trivial root number pair 0,c=4. This proves Collatz's 3n+1 conjecture. Whether a specific an+b conjecture offers a Eulerian tour to all its paired branching numbers can be decided by whether it offers such a tour to paired branching numbers lower than 2a3.