
doi: 10.37236/1197
On a $2m\times 2n$ chessboard, the maximum number of nonattacking kings that can be placed is $mn$, since each $2\times 2$ cell can have at most one king. Let $f_m(n)$ denote the number of ways that $mn$ nonattacking kings can be placed on a $2m\times 2n$ chessboard. The purpose of this paper is to prove the following result. Theorem. For each $m=1,2,3,\ldots $ there are constants $c_m>0$, $d_m$, and $0\le \theta_m < m+1$ such that $$f_m(n)= (c_mn+d_m)(m+1)^n+O(\theta_m^n)\qquad (n\to\infty).$$
Exact enumeration problems, generating functions, chessboard, maximum number, nonattacking kings, number of ways, Factorials, binomial coefficients, combinatorial functions, Other designs, configurations
Exact enumeration problems, generating functions, chessboard, maximum number, nonattacking kings, number of ways, Factorials, binomial coefficients, combinatorial functions, Other designs, configurations
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