Weighted Schreier-type Sets and the Fibonacci Sequence

Abstract: For a finite set $A\subset\mathbb{N}$ and $k\in \mathbb{N}$, let $\omega_k(A) = \sum_{i\in A, i\neq k}1$. For each $n\in \mathbb{N}$, define $$a_{k, n}\ =\ |{E\subset \mathbb{N}\,:\, E = \emptyset\mbox{ or } \omega_k(E) < \min E\leqslant \max E\leqslant n}|.$$ First, we prove that $$a_{k,k+\ell} \ =\ 2F_{k+\ell},\mbox{ for all }\ell\geqslant 0\mbox{ and }k\geqslant \ell+2,$$ where $F_n$ is the $n$th Fibonacci number. Second, we show that $$|{E\subset \mathbb{N}\,:\, \max E = n+1, \min E > \omega_{2,3}(E), \mbox{ and }|E|\neq 2}|\ =\ F_{n},$$ where $\omega_{2,3}(E) = \sum_{i\in E, i\neq 2, 3}1$.