Prime Power Residue and Linear Coverings of Vector Space over $\mathbb{F}_{q}$

Abstract: Let $q$ be an odd prime and $B = {b_{j}}{j=1}^{l}$ be a finite set of nonzero integers that does not contain a perfect $q^{th}$ power. We show that $B$ has a $q^{th}$ power modulo every prime $p \neq q$ and not dividing $\prod{b\in B} b$ if and only if $B$ corrresponds to a linear hyperplane covering of $\mathbb{F}{q}^{k}$. Here, $k$ is the number of distinct prime factors of the $q$-free part of elements of $B$. Consequently: $(i)$ a set $B \subset\mathbb{Z}\setminus{0}$ with cardinality less than $q+1$ cannot have a $q^{th}$ power modulo almost every prime unless it contains a perfect $q^{th}$ power and $(ii)$ For every set $B = {b{j}}{j=1}^{l} \subset\mathbb{Z}\setminus{0}$ and for every $\big(c{j}\big){j=1}^{l} \in\Big(\mathbb{F}{q}\setminus{0}\Big)^{l}$ the set $B$ contains a $q^{th}$ power modulo every prime $p \neq q$ and not dividing $\prod_{j=1}^{l}$ if and only if the set ${b_{j}^{c_{j}}}_{j=1}^{l}$ does so.