Hilbert–Poincaré series

In mathematics, and in particular in the field of algebra, a Hilbert–Poincaré series (also known under the name Hilbert series), named after David Hilbert and Henri Poincaré, is an adaptation of the notion of dimension to the context of graded^{[disambiguation needed]} algebraic structures (where the dimension of the entire structure is often infinite). It is a formal power series in one indeterminate, say t, where the coefficient of tⁿ gives the dimension (or rank) of the sub-structure of elements homogeneous of degree n. It is closely related to the Hilbert polynomial in cases when the latter exists; however, the Hilbert–Poincaré series describes the rank in every degree, while the Hilbert polynomial describes it only in all but finitely many degrees, and therefore provides less information. In particular the Hilbert–Poincaré series cannot be deduced from the Hilbert polynomial even if the latter exists. In good cases, the Hilbert–Poincaré series can be expressed as a rational function of its argument t.

Definition

Let K be a field, and let ${\displaystyle V=\textstyle \bigoplus _{i\in \mathbf {N} }V_{i}}$ be a N-graded vector space over K, where each subspace V_i of vectors of degree n is finite-dimensional. Then the Hilbert–Poincaré series of V is the formal power series

${\displaystyle \sum _{i\in \mathbf {N} }\dim _{K}(V_{i})t^{i}.}$

A similar definition can be given for an N-graded R-module over any commutative ring R in which each submodule of elements homogeneous of a fixed degree n is free of finite rank; it suffices to replace the dimension by the rank. Often the graded vector space or module of which the Hilbert–Poincaré series is considered has additional structure, for instance that of a ring, but the Hilbert–Poincaré series is independent of the multiplicative or other structure.

Example: Since there are ${\displaystyle {\binom {n+k}{n}}}$ monomials of degree k in variables ${\displaystyle X_{0},\dots ,X_{n}}$ (by induction, say), it follows immediately that the Hilbert–Poincaré series of K[X₀,X₁,…,X_n] is ${\displaystyle (1-t)^{-n-1}}$

Hilbert–Serre theorem

Suppose M is a finitely generated graded module over ${\displaystyle A_{0}[x_{0},\dots ,x_{n}],\operatorname {deg} x_{i}=d_{i},A_{0}}$ artinian. Then the Poincaré series of M is a polynomial divided by ${\displaystyle \prod (1-t^{d_{i}})}$.

The proof is by induction on n. If ${\displaystyle n=0}$, then ${\displaystyle M_{k}=0}$ if k is large enough. Next, suppose the theorem is true for ${\displaystyle n-1}$ and consider the exact sequence, with the notation ${\displaystyle N(l)_{k}=N_{k+l}}$,

${\displaystyle 0\to K\to M{\overset {x_{n}}{\to }}M(d_{n})\to C(d_{n})\to 0}$.

Since the length is additive, Poincaré series are also additive. Hence, we have:

${\displaystyle P(M,t)=P(K,t)+P(M(d_{n}),t)-P(C(d_{n}),t)}$.

We can write ${\displaystyle P(M(d_{n}),t)=t^{d_{n}}P(M,t)+}$ a polynomial. Since K is killed by ${\displaystyle x_{n}}$, we can regard it as a graded module over ${\displaystyle A_{0}[x_{0},\dots ,x_{n-1}]}$; the same for C. The theorem thus now follows from the inductive hypothesis.

Chain complex

An example of graded vector space is associated to a chain complex, or cochain complex C of vector spaces; the latter takes the form

${\displaystyle 0\to C^{0}{\stackrel {d_{0}}{\longrightarrow }}C^{1}{\stackrel {d_{1}}{\longrightarrow }}C^{2}{\stackrel {d_{2}}{\longrightarrow }}\cdots {\stackrel {d_{n-1}}{\longrightarrow }}C^{n}\longrightarrow 0.}$

The Hilbert–Poincaré series (here often called the Poincaré polynomial) of the graded vector space ${\displaystyle \bigoplus _{i}C^{i}}$ for this complex is

${\displaystyle P_{C}(t)=\sum _{j=0}^{n}\dim(C^{j})t^{j}.}$

The Hilbert–Poincaré polynomial of the cohomology, with cohomology spaces H^j = H^j(C), is

${\displaystyle P_{H}(t)=\sum _{j=0}^{n}\dim(H^{j})t^{j}.}$

A famous relation between the two is that there is a polynomial ${\displaystyle Q(t)}$ with non-negative coefficients, such that ${\displaystyle P_{C}(t)-P_{H}(t)=(1+t)Q(t).}$