Talk:Collatz conjecture

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Under the section "Other formulations of the conjecture", include some formulations of the Collatz conjecture as termination problems for rewriting systems. These formulations enable automated approaches to the Collatz conjecture by using methods that are developed for automatically proving termination of rewriting.

For this change, please add the following after the section "As a tag system" under "Other formulations of the conjecture".

For this section, assume that the Collatz function is defined in the slightly modified form:

${\displaystyle f(n)={\begin{cases}{\frac {n}{2}}&{\text{if }}n\equiv 0\\[4px]{\frac {3n+1}{2}}&{\text{if }}n\equiv 1\end{cases}}{\pmod {2}}}$

The termination of the following string rewriting system is equivalent to the Collatz conjecture:^[1]

${\displaystyle {\begin{array}{rcl}{\mathtt {h}}{\mathtt {1}}{\mathtt {1}}&\to &{\mathtt {1}}{\mathtt {h}}\end{array}}\qquad {\begin{array}{rcl}{\mathtt {1}}{\mathtt {1}}{\mathtt {h}}{\mathtt {b}}&\to &{\mathtt {1}}{\mathtt {1}}{\mathtt {s}}{\mathtt {b}}\\{\mathtt {1}}{\mathtt {s}}&\to &{\mathtt {s}}{\mathtt {1}}\\{\mathtt {b}}{\mathtt {s}}&\to &{\mathtt {b}}{\mathtt {h}}\end{array}}\qquad {\begin{array}{rcl}{\mathtt {h}}{\mathtt {1}}{\mathtt {b}}&\to &{\mathtt {t}}{\mathtt {1}}{\mathtt {1}}{\mathtt {b}}\\{\mathtt {1}}{\mathtt {t}}&\to &{\mathtt {t}}{\mathtt {1}}{\mathtt {1}}{\mathtt {1}}\\{\mathtt {b}}{\mathtt {t}}&\to &{\mathtt {b}}{\mathtt {h}}\end{array}}}$

The above rewriting system represents each number in unary, and applications of its rules in any order to such a representation simulates the iterated applications of the Collatz function. Roughly speaking, this system simulates the execution of a Turing machine with cells that can be contracted or expanded, where ${\displaystyle {\mathtt {h}}}$, ${\displaystyle {\mathtt {s}}}$, ${\displaystyle {\mathtt {t}}}$ indicate the position of the head along with the state, ${\displaystyle {\mathtt {b}}}$ stands for the blank characters on the tape, and the symbol ${\displaystyle {\mathtt {1}}}$ is the unary digit.

An alternative string rewriting system that uses mixed binary–ternary representations of numbers is as follows:^[2]

${\displaystyle {\begin{array}{rcl}{\mathtt {f}}\triangleright &\to &\triangleright \\{\mathtt {t}}\triangleright &\to &{\mathtt {2}}\triangleright \end{array}}\qquad {\begin{array}{rcl}{\mathtt {f}}{\mathtt {0}}&\to &{\mathtt {0}}{\mathtt {f}}\\{\mathtt {f}}{\mathtt {1}}&\to &{\mathtt {0}}{\mathtt {t}}\\{\mathtt {f}}{\mathtt {2}}&\to &{\mathtt {1}}{\mathtt {f}}\end{array}}\qquad {\begin{array}{rcl}{\mathtt {t}}{\mathtt {0}}&\to &{\mathtt {1}}{\mathtt {t}}\\{\mathtt {t}}{\mathtt {1}}&\to &{\mathtt {2}}{\mathtt {f}}\\{\mathtt {t}}{\mathtt {2}}&\to &{\mathtt {2}}{\mathtt {t}}\end{array}}\qquad {\begin{array}{rcl}\triangleleft {\mathtt {0}}&\to &\triangleleft {\mathtt {t}}\\\triangleleft {\mathtt {1}}&\to &\triangleleft {\mathtt {f}}{\mathtt {f}}\\\triangleleft {\mathtt {2}}&\to &\triangleleft {\mathtt {f}}{\mathtt {t}}\end{array}}}$

In the above system, the symbols ${\displaystyle {\mathtt {f}}}$ and ${\displaystyle {\mathtt {t}}}$ represent the binary digits (0 and 1), while the symbols ${\displaystyle {\mathtt {0}}}$, ${\displaystyle {\mathtt {1}}}$, ${\displaystyle {\mathtt {2}}}$ represent the ternary digits. The symbols ${\displaystyle \triangleleft }$ and ${\displaystyle \triangleright }$ act as delimiters. The rules in the first column apply the Collatz function to a number represented in mixed base as long as the rightmost digit is binary. The remaining rules rewrite the representation (while preserving the value it represents) such that the rightmost digit is binary.

Rephrasing the Collatz conjecture as termination of string rewriting enables, at least in principle, using automated approaches to try to prove the conjecture thanks to the methods developed for automatically proving termination of rewriting.

46.196.80.203 (talk) 13:49, 17 June 2024 (UTC)[reply]

 Not done: This seems a bit WP:TOOSOON to me. It's based on a paper that's less than a year old with few citations. PianoDan (talk) 22:32, 18 June 2024 (UTC)[reply]

The paper by Zantema is from 2005, so it is ~19 years old. The other paper by Yolcu, Aaronson, and Heule is actually ~3 years old; the conference version of their paper is here: https://doi.org/10.1007/978-3-030-79876-5_27. The latter work was also featured in 2021 in popular science magazines, for instance: https://www.technologyreview.com/2021/07/02/1027475/computers-ready-solve-this-notorious-math-problem. 46.196.80.203 (talk) 09:52, 24 June 2024 (UTC)[reply]

 Not done for now: please establish a consensus for this alteration before using the {{Edit semi-protected}} template. I still don't think it's warranted based on the level of citations it has received. Given that there is disagreement from at least one editor that this material should be included in the article, the "Edit request template" procedure no longer applies, since it's only for non-controversial edits. Instead, you can attempt to build a consensus on this page that the material should be included. PianoDan (talk) 16:29, 24 June 2024 (UTC)[reply]

I fail to see why the citation count of the source material should be a significant basis for the decision of whether to include some content on the page, but let's assume it should be: Arguably the most similar content currently visible on the page is Liesbeth De Mol's 2-tag system from the 2008 paper. According to Google Scholar, that paper has 36 citations since 2008. Zantema's paper has 64 citations since 2005, and YAH's (conference) paper has 12 citations since 2021. To my understanding, the edit decision should be made based on the significance of the content and whether it is interesting enough. I think those rewriting systems are somewhat more interesting than the tag system since they enable an entirely new approach (at least in principle) towards a proof of the conjecture. 46.196.80.203 (talk) 11:09, 25 June 2024 (UTC)[reply]

The chapter Collatz_conjecture#As_an_abstract_machine_that_computes_in_base_two

1. already states that the number of trailing binary zeroes equals the number of next repeated divisions (/2). That is obvious.
2. but it does not yet state that the number of trailing binary ones equals the next number of increments, (*3+1)/2, as the number of trailing ones decreases by one with each increment.

Example:

• 19: 10011 (2 next increments)
• 29 : 11101 (1 next increment)
• 44: 101100 (no immediate increment) The trailing 1100 indicates: after two decrements (22, 11), two increments will follow (17, 26).

The source (BOM - Beauty Of Mathematics) claims at https://www.youtube.com/watch?v=UZH3P8Ey_C8

• not to be a mathematician just working on it as a hobby, so a primary source.
• this does not proof the conjecture, but it might lead to one.

Any mathematician known to have picked this up? Any secondary source known?

The graph already shows the total number of binary ones in brackets.

Is there any graph available that shows the number of trailing ones? Uwappa (talk) 07:46, 25 June 2024 (UTC)[reply]

There does not seem to be a graph yet that shows how a Collatz sequence impacts trailing bits of binary numbers.

Created a graph for Collatz_conjecture#As_an_abstract_machine_that_computes_in_base_two showing how the Collatz conjecture 'nibbles' on trailing bits, binary ones and zeroes:

Uwappa (talk) 13:28, 14 July 2024 (UTC)[reply]

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The definition says: "If the previous term is even, the next term is one half of the previous term. If the previous term is odd, the next term is 3 times the previous term plus 1.". So, you can not choose non-integers for the Collatz conjecture and the sections Iterating on rationals with odd denominators, 2-adic extension and Iterating on real or complex numbers need to be removed. 94.31.89.138 (talk) 18:01, 20 August 2024 (UTC)[reply]

And the section talks about it being an extension of the map.Naraht (talk) 18:03, 23 September 2024 (UTC)[reply]

All of these sections define clearly and properly what they mean and are adequately sourced. —David Eppstein (talk) 18:39, 23 September 2024 (UTC)[reply]

What is/are the references/citations that disclose the information in paragraph "Iterating on all integers"? 45.50.231.56 (talk) 15:11, 23 September 2024 (UTC)[reply]

I think much of this can be found in Lagarias 1985 section 2.6 and its references. —David Eppstein (talk) 17:26, 23 September 2024 (UTC)[reply]