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A chain of $4n+2$ of $2n+1$-gon

I posed a generalization of Theorem 3.2 In my paper

Conjecture: Let $P_1, P_2,....,P_{2n+1}$ and $O$ be $2n+2$ points in plane. Construct a chain $2n+1$ regular ${2n+1}$-gons $A_{11}A_{12}...A_{1\;2n+1}$; ....;$A_{2n+1\;1}A_{2n+1\;2}...A_{2n+1\;2n+1}$ with center $A_1, A_2...., A_{2n+1}$ such that $O=A_{11}$, $A_{12}=A_1$, $A_{2\;1}=A_{13}$, $A_{2\;2}=A_{2}$, $A_{i+1\;1}=A_{i3}$, $A_{i+1\;2}=A_{i+1}$ for $i=\overline{1\;2n}$

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Continuing construct a chain $2n+1$ regular ${2n+1}$-gons $B_{11}B_{12}...B_{1\;2n+1}$; ....;$B_{2n+1\;1}B_{2n+1\;2}...B_{2n+1\;2n+1}$ with centers $B_1, B_2...., B_{2n+1}$, such that $B_{11}=A_{2n+1\;3}$, $B_{12}=P_1$, $B_{2\;1}=B_{13}$, $B_{2\;2}=P_{2}$, $B_{i+1\;1}=B_{i3}$, $B_{i+1\;2}=P_{i+1}$ for $i=\overline{1\;2n}$.

Then $B_{2n+1\;3}=O$ and segments $A_1B_1=A_2B_2=...=A_{2n+1}B_{2n+1}$ and $\angle A_iB_i, A_{i+1}B_{i+1}=\frac{(2n-1)\pi}{2n+1}$

Corollary: $B_{2n+1\;3}$ is fixed point when $P_1$, $P_2$, ....,$P_n$ be moved.

Question 1: Is the conjecture correct?

Question 2: Let $P_1$, $P_2$, ....,$P_n$ are fixed point in the plane, find position of $O$ such that $A_{2n+1\;3}=O$

See also:

PS: In the conjecture, all regular polygon is same direction.