
doi: 10.37236/1212
Let $f(n)$ denote the number of configurations of $n^2$ mutually non-attacking kings on a $2n\times 2n$ chessboard. We show that $\log f(n)$ grows like $2n\log n - 2n\log 2$, with an error term of $O(n^{4/5}\log n)$. The result depends on an estimate for the sum of the entries of a high power of a matrix with positive entries.
kings, number of configurations, Exact enumeration problems, generating functions, chessboard, Factorials, binomial coefficients, combinatorial functions, Other designs, configurations, Game theory, matrix
kings, number of configurations, Exact enumeration problems, generating functions, chessboard, Factorials, binomial coefficients, combinatorial functions, Other designs, configurations, Game theory, matrix
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