Beaver Math Olympiad: Difference between revisions

Beaver Mathematical Olympiad (BMO) is an attempt to re-formulate the halting problem for some particular Turing machines as a mathematical problem in a style suitable for a hypothetical math olympiad.

The purpose of the BMO is twofold. First, statements where every non-essential details (e.g. related to tape encoding, number of steps, etc) are discarded are more suitable to be shared with mathematicians who perhaps are able to help. Second, it's a way to jokingly highlight how a hard question could appear deceptively simple.

Unsolved problems

1RB1RE_1LC0RA_0RD1LB_---1RC_1LF1RE_0LB0LE

Let ${\displaystyle (a_{n})_{n\geq 1}}$ and ${\displaystyle (b_{n})_{n\geq 1}}$ be two sequences such that ${\displaystyle (a_{1},b_{1})=(1,2)}$ and

$${\displaystyle (a_{n+1},b_{n+1})={\begin{cases}(a_{n}-b_{n},4b_{n}+2)&{\text{if }}a_{n}\geq b_{n}\\(2a_{n}+1,b_{n}-a_{n})&{\text{if }}a_{n}<b_{n}\end{cases}}}$$

for all positive integers ${\displaystyle n}$. Does there exist a positive integer ${\displaystyle i}$ such that ${\displaystyle a_{i}=b_{i}}$?

The first 10 values of ${\displaystyle (a_{n},b_{n})}$ are ${\displaystyle (1,2),(3,1),(2,6),(5,4),(1,18),(3,17),(7,14),(15,7),(8,30),(17,22)}$.

Hydra and Antihydra

Let ${\displaystyle (a_{n})_{n\geq 0}}$ be a sequence such that ${\displaystyle a_{n+1}=a_{n}+\left\lfloor {\frac {a_{n}}{2}}\right\rfloor }$ for all non-negative integers ${\displaystyle n}$.

1. If ${\displaystyle a_{0}=3}$, does there exist a non-negative integer ${\displaystyle k}$ such that the list of numbers ${\displaystyle a_{0},a_{1},a_{2},\dots ,a_{k}}$ have more than twice as many even numbers as odd numbers? (Hydra)
2. If ${\displaystyle a_{0}=8}$, does there exist a non-negative integer ${\displaystyle k}$ such that the list of numbers ${\displaystyle a_{0},a_{1},a_{2},\dots ,a_{k}}$ have more than twice as many odd numbers as even numbers? (Antihydra)

Solved problems

1RB0RB3LA4LA2RA_2LB3RA---3RA4RB (bbch) and 1RB1RB3LA4LA2RA_2LB3RA---3RA4RB (bbch)

Let ${\displaystyle v_{2}(n)}$ be the largest integer ${\displaystyle k}$ such that ${\displaystyle 2^{k}}$ divides ${\displaystyle n}$. Let ${\displaystyle (a_{n})_{n\geq 0}}$ be a sequence such that

$${\displaystyle a_{n}={\begin{cases}2&{\text{if }}n=0\\a_{n-1}+2^{v_{2}(a_{n-1})+2}-1&{\text{if }}n\geq 1\end{cases}}}$$

for all non-negative integers ${\displaystyle n}$. Is there an integer ${\displaystyle n}$ such that ${\displaystyle a_{n}=4^{k}}$ for some positive integer ${\displaystyle k}$?

Link to Discord discussion: https://discord.com/channels/960643023006490684/1084047886494470185/1252634913220591728

1RB3RB---1LB0LA_2LA4RA3LA4RB1LB (bbch)

Bonnie the beaver was bored, so she tried to construct a sequence of integers ${\displaystyle \{a_{n}\}_{n\geq 0}}$. She first defined ${\displaystyle a_{0}=2}$, then defined ${\displaystyle a_{n+1}}$ depending on ${\displaystyle a_{n}}$ and ${\displaystyle n}$ using the following rules:

• If ${\displaystyle a_{n}\equiv 0{\text{ (mod 3)}}}$, then ${\displaystyle a_{n+1}={\frac {a_{n}}{3}}+2^{n}+1}$.
• If ${\displaystyle a_{n}\equiv 2{\text{ (mod 3)}}}$, then ${\displaystyle a_{n+1}={\frac {a_{n}-2}{3}}+2^{n}-1}$.

With these two rules alone, Bonnie calculates the first few terms in the sequence: ${\displaystyle 2,0,3,6,11,18,39,78,155,306,\dots }$. At this point, Bonnie plans to continue writing terms until a term becomes ${\displaystyle 1{\text{ (mod 3)}}}$. If Bonnie sticks to her plan, will she ever finish?

Solution

How to guess the closed-form solution: Firstly, notice that ${\displaystyle a_{n}\approx {\frac {3}{5}}\times 2^{n}}$. Secondly, calculate the error term ${\displaystyle a_{n}-{\frac {3}{5}}\times 2^{n}}$. The error term appears to have a period of 4. This leads to the following guess:

$${\displaystyle a_{n}={\frac {3}{5}}{\begin{cases}2^{n}+{\frac {7}{3}}&{\text{if }}n\equiv 0{\pmod {4}}\\2^{n}-2&{\text{if }}n\equiv 1{\pmod {4}}\\2^{n}+1&{\text{if }}n\equiv 2{\pmod {4}}\\2^{n}+2&{\text{if }}n\equiv 3{\pmod {4}}\\\end{cases}}}$$

This closed-form solution can be proven correct by induction. Unfortunately, the induction may require a lot of tedious calculations.

For all ${\displaystyle k}$, we have ${\displaystyle a_{4k}\equiv 2{\text{ (mod 3)}}}$ and ${\displaystyle a_{4k+1}\equiv a_{4k+2}\equiv a_{4k+3}\equiv 0{\text{ (mod 3)}}}$. Therefore, Bonnie will never finish.