Hilbert-Samuel polynomial: Difference between revisions

Definition

Let ${\displaystyle A}$ be a Noetherian local ring with unique maximal ideal ${\displaystyle {\mathfrak {m}}}$. Let ${\displaystyle M}$ be a finitely generated ${\displaystyle A}$-module, and ${\displaystyle I}$ be an ideal of finite colength in ${\displaystyle A}$ (in other words, there exists a ${\displaystyle n}$ such that ${\displaystyle {\mathcal {m}}^{n}\subset I\subset {\mathcal {m}}}$).

Consider an essentially ${\displaystyle I}$-adic filtration of ${\displaystyle M}$, i.e. a descending chain:

${\displaystyle M=M_{0}\supset M_{1}\supset M_{2}\supset \ldots }$

such that there exists ${\displaystyle n_{0}}$ such that ${\displaystyle M_{n+1}=IM_{n}}$ for ${\displaystyle n\geq n_{0}}$.

The Hilbert-Samuel function for this filtration is a function sending a positive integer ${\displaystyle d}$ to the length of the quotient ${\displaystyle M_{d-1}/M_{d}}$ as an ${\displaystyle A}$-module. This Hilbert-Samuel function turns out to be equal to a polynomial for sufficiently large values of ${\displaystyle d}$. That polynomial is termed the Hilbert-Samuel polynomial for the filtration.

Some people use the term Hilbert-Samuel polynomial for the length polynomial, which is the polynomial measuring the length of the module ${\displaystyle M_{0}/M_{d}}$.

When we simply talk of the Hilbert-Samuel polynomial, we by default refer to that for the ring as a module over itself. The default ideal is taken to be the maximal ideal and the default filtration is taken to be the standard one.

Facts

• The specific Hilbert-Samuel polynomial depends on the specific filtration we choose. However, the leading coefficient of the Hilbert-Samuel polynomial depends only on the ideal ${\displaystyle I}$.
• The leading coefficient depends on the specific choice of the Hilbert-Samuel polynomial. However, the degree is independent of the choice of ${\displaystyle I}$.
• For a Noetherian local ring ${\displaystyle R}$, the degree of the Hilbert-Samuel polynomial equals the Krull dimension.