General Dynamics and Generation Mapping for Collatz-type Sequences

Abstract

Let an odd integer \(X\) be expressed as \ΣM > mbM2M\+2m-1, where bM∈\0,1\ and 2m-1 is referred to as the Governor. In Collatz-type functions, a high index Governor is eventually reduced to 21-1. For the 3Z+1 sequence, the Governor occurring in the Trivial cycle is 21-1, while for the 5Z+1 sequence, the Trivial Governors are 22-1 and 21-1. Therefore, in these specific sequences, the Collatz function reduces the Governor 2m - 1 to the Trivial Governor 2T - 1. Once this Trivial Governor is reached, it can evolve to a higher index Governor through interactions with other terms. This feature allows X to reappear in a Collatz-type sequence, since 2m - 1 = 2m - 1 + ·s + 2T + 1 + 2T+(2T-1). Thus, if X reappears, at least one odd ancestor of \ΣM > mbM2M\+2m-1+·s+2T+1+2T+(2T-1) must have the Governor 2m-1. Ancestor mapping shows that all odd ancestors of X have the Trivial Governor for the respective Collatz sequence. This implies that odd integers that repeat in the 3Z + 1 sequence have the Governor 21 - 1, while those forming a repeating cycle in the 5Z + 1 sequence have either 22 - 1 or 21 - 1 as the Governor. Successor mapping for the 3Z + 1 sequence further indicates that there are no auxiliary cycles, as the Trivial Governor is always transformed into a different index Governor. Similarly, successor mapping for the 5Z + 1 sequence reveals that the smallest odd integers forming an auxiliary cycle are smaller than 25. Finally, attempts to identify integers that diverge for the 3Z + 1 sequence suggest that no such integers exist.