Specifically, consider a lattice L in Euclidean space Rⁿ and an n-dimensional polytope P in Rⁿ, and assume that all vertices of the polytope are points of the lattice. (A common example is L = Zⁿ and a polytope with all its vertex coordinates being integers.) For any positive integer t, let tP be the t-fold dilation of P and let L(P, t) be the number of lattice points contained in tP. Ehrhart showed in 1967 that L is a rational polynomial of degree n in t, i.e. there exist rational numbers a₀,...,a_n such that

L(P, t) = a_ntⁿ + a_n-1t^n-1 + ... + a₀     for all positive integers t

• the leading coefficient, a_n, is equal to the n-dimensional volume of P, divided by d(L) (see lattice for an explanation of the content d(L) of a lattice),
• the second coefficient, a_n-1, can be computed as follows: the lattice L induces a lattice L_F on any face F of P; take the (n-1)-dimensional volume of F, divide by 2d(L_F), and add those numbers for all faces of P
• the constant coefficient a₀ is the Euler characteristic of P.

The Ehrhart polynomial of the interior of a closed polytope P can be computed as

L(int P, t) = (-1)ⁿ L(P, −t).