> **Question 1:** I am looking for a proof of the conjectures 1, 2, 3 as follows?
> **Question 2:** In conjecture 3, in general case, I can not give a formula of $X$. But I think
* If $n$ is odd number and $gcd(n,k)=1$ then $X=\frac{2nk}{gcd(k,k-2)}$, I checked with some small case.
* If $n$ is even number and $gcd(n,k)=1$ then $X=\frac{nk}{gcd(k,k-2)}$, I checked with some small case.
Can You give a general formula of $X$?
Consider $n, k \ge 3$ be two integer numbers, given $n$ general points $P_1$, $P_2$,....,$P_n$ and $O$ is arbitrary point in the plane, let $P_{n+i}=P_i$ for $i=1,\ldots,....$. Construct a chain of $m$ regular $k$-gon:
* Construct First $k$-gon: $A_{1\;1}A_{1\;2}....A_{1\;k}$ such that $A_{1\;1}=O$; $A_{1\;2}=P_1$, the centroid of the first $k$-gon is $A_1$
* Second $k$-gon: $A_{2\;1}A_{2\;2}....A_{2\;k}$ such that $A_{2\;1}=A_{1\;3}$; $A_{2\;2}=P_2$ the centroid of the second $k$-gon is $A_2$
* $.................................$
* $i$ th $k$-gon: $A_{i\;1}A_{i\;2}....A_{i\;k}$ such that $A_{i+1\;1}=A_{i\;3}$; $A_{i+1\;2}=P_{i+1}$ the centroid of the $i$ th $k$-gon is $A_i$
* $.................................$
* $m$ th $k$-gon: $A_{m\;1}A_{m\;2}....A_{m\;k}$ such that $A_{m\;1}=A_{m-1\;3}$; $A_{m\;2}=P_{m}$ the centroid of the $m$ th $k$-gon is $A_m$
and all regular polygon is same direction.
**Definition:** The chain is closed if exist $m$ such that $A_{m\;3}=A_{1\;1}=O$. The chain is open if no exist $m$ such that $A_{m\;3}=A_{1\;1}=O$
**Conjecture 1:** If $n=\frac{2k}{gcd(k-2,2k)}$ then the chain is opened.
**Conjecture 2:** If $n\ne\frac{2k}{gcd(k-2,2k)}$ then the chain is closed.
**Conjecture 3:** If the chain is closed then $m=n*X$ and $X$ points $A_i, A_{n+i}, A_{2n+i},...,A_{nx+i}$ be form $X$-gon for $i=1, 2,...,n$ which the centroid of the $X$-gon is fixed when we moved $O$, these regular polygon equal.
[![enter image description here][1]][1]
**See also:**
* [Napoleon theorem](https://en.wikipedia.org/wiki/Napoleon%27s_theorem)
* [Van Aubel theorem](https://en.wikipedia.org/wiki/Van_Aubel%27s_theorem)
* [Petr–Douglas–Neumann theorem](https://en.wikipedia.org/wiki/Petr%E2%80%93Douglas%E2%80%93Neumann_theorem)
[1]: https://i.sstatic.net/mXHx7.png