Collatz-like: Difference between revisions

A Collatz-like function is a partial function defined piecewise depending on the remainder of an input modulo some number. The canonical example is the original Collatz function:$${\displaystyle \begin{array}{lll}c(2k)& =& k\\ c(2k+1)& =& 3k+2\end{array}}$$

A Collatz-like problem is a question about the behavior of iterating a Collatz-like function. Collatz-like problems are famously difficult.

Many Busy Beaver Champions have Collatz-like behavior, meaning that their behavior can be concisely described via the iterated values of a Collatz-like function.

Examples

5-state busy beaver winner

Consider the 5-state busy beaver winner and the generalized configuration:

$${\displaystyle M(n)=0^{\mathrm{\infty }}\text{<mo><</mo>}\text{A}{1}^n{0}^{\mathrm{\infty }}}$$Pascal Michel showed that:

$${\displaystyle \begin{array}{lcl}{0}^{\mathrm{\infty }}\text{<mo><</mo>}\text{A}{0}^{\mathrm{\infty }}& =& M(0)\\ M(3k)& \stackrel{5k^2+19k+15}{\to }& M(5k+6)\\ M(3k+1)& \stackrel{5k^2+25k+27}{\to }& M(5k+9)\\ M(3k+2)& \stackrel{6k+12}{\to }& 0^{\mathrm{\infty }}1\text{Z}\text{<mo>></mo>}01{(001)}^{k+1}10^{\mathrm{\infty }}\end{array}}$$

Starting on a blank tape ${\displaystyle M(0)}$, these rules iterate 15 times before reaching the halt config.^[1]

Hydra

Consider Hydra and the generalized configuration:

$${\displaystyle C(a,b)=0^{\mathrm{\infty }}\text{<mo><</mo>}\text{A}20^{3(a-2)}{3}^{b}20^{\mathrm{\infty }}}$$ Daniel Yuan showed that:$${\displaystyle \begin{array}{llll}{0}^{\mathrm{\infty }}\text{A}\text{<mo>></mo>}{0}^{\mathrm{\infty }}& & \stackrel{20}{\to }& C(3,0)\\ C(2n,& 0)& \to & \text{Halt}(9n-6)\\ C(2n,& b+1)& \to & C(3n,b)\\ C(2n+1,& b)& \to & C(3n+1,b+2)\end{array}}$$

Where ${\displaystyle \text{Halt}(n)}$ is a halting configuration with ${\displaystyle n}$ non-zero symbols on the tape.

Starting from ${\displaystyle C(3,0)}$, this simulates a pseudo-random walk along the ${\displaystyle b}$ parameter, increasing it by 2 every time ${\displaystyle a}$ is odd, decreasing by 1 every time it's even. Deciding whether or not Hydra halts requires determining whether through the process of applying the Collatz-like function $${\displaystyle \begin{array}{llll}H(2n)& =& 3n& \text{(even transition)}\\ H(2n+1)& =& 3n+1& \text{(odd transition)}\end{array}}$$ to 3 recursively, there eventually comes a point where the amount of even transitions applied is more than twice the amount of odd transitions applied.^[2] The first few transitions are displayed below: $${\displaystyle \begin{array}{l}\phantom{\frac{\frac{0}{.}}{.}}3\stackrel{O}{\to }4\stackrel{E}{\to }6\stackrel{E}{\to }9\stackrel{O}{\to }13\stackrel{O}{\to }19\stackrel{O}{\to }28\stackrel{E}{\to }42\stackrel{E}{\to }63\stackrel{O}{\to }\cdots \end{array}}$$

Exponential Collatz

Consider the machine 1RB0LD_1RC0RF_1LC1LA_0LE1RZ_1LF0RB_0RC0RE (bbch), discovered by Pavel Kropitz in May 2022, and the general configuration:$${\displaystyle K(n):=0^{\mathrm{\infty }}10^{n}110^5\text{C}\text{<mo>></mo>}{0}^{\mathrm{\infty }}}$$Shawn Ligocki showed that: $${\displaystyle \begin{array}{lll}{0}^{\mathrm{\infty }}\text{A}\text{<mo>></mo>}{0}^{\mathrm{\infty }}& \stackrel{45}{\to }& K(5)\\ K(4k)& \to & \mathrm{Halt}\left(\frac{3^{k+3}-11}{2}\right)\\ K(4k+1)& \to & K\left(\frac{3^{k+3}-11}{2}\right)\\ K(4k+2)& \to & K\left(\frac{3^{k+3}-11}{2}\right)\\ K(4k+3)& \to & K\left(\frac{3^{k+3}+1}{2}\right)\end{array}}$$

Demonstrating Collatz-like behavior with exponential piecewise component functions.

Starting from config ${\displaystyle K(5)}$, these rules iterate 15 times before reaching the halt config leaving over ${\displaystyle 10\uparrow \uparrow 15}$ non-zero symbols on the tape.^[3]

References