Abstract
The nth Birkhoff polytope is the set of all doubly stochastic n × n matrices, that is, those matrices with nonnegative real coefficients in which every row and column sums to one. A wide open problem concerns the volumes of these polytopes, which have been known for n $\leq$ 8. We present a new, complex-analytic way to compute the Ehrhart polynomial of the Birkhoff polytope, that is, the function counting the integer points in the dilated polytope. One reason to be interested in this counting function is that the leading term of the Ehrhart polynomial is—up to a trivial factor—the volume of the polytope. We implemented our methods in the form of a computer program, which yielded the Ehrhart polynomial (and hence the volume) of the ninth Birkhoff polytope, as well as the volume of the tenth Birkhoff polytope.
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Beck, M., Pixton, D. The Ehrhart Polynomial of the Birkhoff Polytope. Discrete Comput Geom 30, 623–637 (2003). https://doi.org/10.1007/s00454-003-2850-8
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DOI: https://doi.org/10.1007/s00454-003-2850-8