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Spherical containment and the Minkowski dimension of partial orders

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Abstract

The recent work on circle orders generalizes to higher dimensional spheres. As spherical containment is equivalent to causal precedence in Minkowski space, we define the Minkowski dimension of a poset to be the dimension of the minimal Minkowski space into which the poset can be embedded; this isd if the poset can be represented by containment with spheresS d−2 and of no lower dimension. Comparing this dimension with the standard dimension of partial orders we prove that they are identical in dimension two but not in higher dimensions, while their irreducible configurations are the same in dimensions two and three. Moreover, we show that there are irreducible configurations for arbitrarily large Minkowski dimension, thus providing a lower bound for the Minkowski dimension of partial orders.

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  1. David A. Meyer

    Present address: Project in Geometry and Physics, Department of Mathematics, UCSD, 92093-0112, La Jolla, CA

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  1. Department of Physics, Syracuse University, 13244-1130, Syracuse, NY, U.S.A.

    David A. Meyer

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  1. David A. Meyer
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Communicated by I. Rival

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Meyer, D.A. Spherical containment and the Minkowski dimension of partial orders. Order 10, 227–237 (1993). https://doi.org/10.1007/BF01110544

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