Bernstein–Kushnirenko theorem

Template:Short description The Bernstein–Kushnirenko theorem (or Bernstein–Khovanskii–Kushnirenko (BKK) theorem^[1]), proven by David Bernstein^[2] and Template:Interlanguage link multi^[3] in 1975, is a theorem in algebra. It states that the number of non-zero complex solutions of a system of Laurent polynomial equations ${\displaystyle f_1=\cdots =f_n=0}$ is equal to the mixed volume of the Newton polytopes of the polynomials ${\displaystyle f_1,\dots ,f_n}$, assuming that all non-zero coefficients of ${\displaystyle f_n}$ are generic. A more precise statement is as follows:

Let ${\displaystyle A}$ be a finite subset of ${\displaystyle {\mathbb{Z}}^n.}$ Consider the subspace ${\displaystyle L_A}$ of the Laurent polynomial algebra ${\displaystyle ℂ[x_1^{\pm 1},\dots ,x_n^{\pm 1}]}$ consisting of Laurent polynomials whose exponents are in ${\displaystyle A}$. That is:

${\displaystyle L_A=\{f|f(x)=\sum _{\alpha \in A}{c}_{\alpha }{x}^{\alpha },c_{\alpha }\in ℂ\},}$

where for each ${\displaystyle \alpha =(a_1,\dots ,a_n)\in {\mathbb{Z}}^n}$ we have used the shorthand notation ${\displaystyle x^{\alpha }}$ to denote the monomial ${\displaystyle x_1^{a_1}\cdots x_n^{a_n}.}$

Now take ${\displaystyle n}$ finite subsets ${\displaystyle A_1,\dots ,A_n}$ of ${\displaystyle {\mathbb{Z}}^n}$, with the corresponding subspaces of Laurent polynomials, ${\displaystyle L_{A_1},\dots ,L_{A_n}.}$ Consider a generic system of equations from these subspaces, that is:

${\displaystyle f_1(x)=\cdots =f_n(x)=0,}$

where each ${\displaystyle f_i}$ is a generic element in the (finite dimensional vector space) ${\displaystyle L_{A_i}.}$

The Bernstein–Kushnirenko theorem states that the number of solutions ${\displaystyle x\in (ℂ\setminus 0{)}^n}$ of such a system is equal to

${\displaystyle n!V({\mathrm{\Delta }}_1,\dots ,{\mathrm{\Delta }}_n),}$

where ${\displaystyle V}$ denotes the Minkowski mixed volume and for each ${\displaystyle i,{\mathrm{\Delta }}_i}$ is the convex hull of the finite set of points ${\displaystyle A_i}$. Clearly, ${\displaystyle {\mathrm{\Delta }}_i}$ is a convex lattice polytope; it can be interpreted as the Newton polytope of a generic element of the subspace ${\displaystyle L_{A_i}}$.

In particular, if all the sets ${\displaystyle A_i}$ are the same, ${\displaystyle A=A_1=\cdots =A_n,}$ then the number of solutions of a generic system of Laurent polynomials from ${\displaystyle L_A}$ is equal to

${\displaystyle n!\mathrm{vol}(\mathrm{\Delta }),}$

where ${\displaystyle \mathrm{\Delta }}$ is the convex hull of ${\displaystyle A}$ and vol is the usual ${\displaystyle n}$-dimensional Euclidean volume. Note that even though the volume of a lattice polytope is not necessarily an integer, it becomes an integer after multiplying by ${\displaystyle n!}$.

Kushnirenko's name is also spelt Kouchnirenko. David Bernstein is a brother of Joseph Bernstein. Askold Khovanskii has found about 15 different proofs of this theorem.^[4]

Template:Reflist

• Bézout's theorem for another upper bound on the number of common zeros of Template:Mvar polynomials in Template:Mvar indeterminates.