The Ehrhart polynomial LPβ of an integral polytope P counts the number of
integer points in integral dilates of P. Ehrhart polynomials of polytopes are
often described in terms of their Ehrhart hβ-vector (aka Ehrhart
Ξ΄-vector), which is the vector of coefficients of LPβ with respect to
a certain binomial basis and which coincides with the h-vector of a regular
unimodular triangulation of P (if one exists). One important result by
Stanley about hβ-vectors of polytopes is that their entries are always
non-negative. However, recent combinatorial applications of Ehrhart theory give
rise to polytopal complexes with hβ-vectors that have negative entries.
In this article we introduce the Ehrhart fβ-vector of polytopes or, more
generally, of polytopal complexes K. These are again coefficient vectors of
LKβ with respect to a certain binomial basis of the space of polynomials and
they have the property that the fβ-vector of a unimodular simplicial complex
coincides with its f-vector. The main result of this article is a counting
interpretation for the fβ-coefficients which implies that fβ-coefficients
of integral polytopal complexes are always non-negative integers. This holds
even if the polytopal complex does not have a unimodular triangulation and if
its hβ-vector does have negative entries. Our main technical tool is a new
partition of the set of lattice points in a simplicial cone into discrete
cones. Further results include a complete characterization of Ehrhart
polynomials of integral partial polytopal complexes and a non-negativity
theorem for the fβ-vectors of rational polytopal complexes.Comment: 19 pages, 1 figur