In mathematics, an integer-valued polynomial (also known as a numerical polynomial)
P(t)
P(n)
P(t)=
| 1 | |
| 2 |
t2+
| 1 | t= | |
| 2 |
| 1 | |
| 2 |
t(t+1)
takes on integer values whenever t is an integer. That is because one of t and
t+1
Integer-valued polynomials are objects of study in their own right in algebra, and frequently appear in algebraic topology.[1]
\Q[t]
Pk(t)=t(t-1) … (t-k+1)/k!
for
k=0,1,2,...
Integer-valued polynomials may be used effectively to solve questions about fixed divisors of polynomials. For example, the polynomials P with integer coefficients that always take on even number values are just those such that
P/2
In questions of prime number theory, such as Schinzel's hypothesis H and the Bateman–Horn conjecture, it is a matter of basic importance to understand the case when P has no fixed prime divisor (this has been called Bunyakovsky's property, after Viktor Bunyakovsky). By writing P in terms of the binomial coefficients, we see the highest fixed prime divisor is also the highest prime common factor of the coefficients in such a representation. So Bunyakovsky's property is equivalent to coprime coefficients.
As an example, the pair of polynomials
n
n2+2
p=3
n
n(n2+2)
is divisible by 3, which follows from the representation
n(n2+2)=6\binom{n}{3}+6\binom{n}{2}+3\binom{n}{1}
with respect to the binomial basis, where the highest common factor of the coefficients - hence the highest fixed divisor of
n(n2+2)
Numerical polynomials can be defined over other rings and fields, in which case the integer-valued polynomials above are referred to as classical numerical polynomials.
The K-theory of BU(n) is numerical (symmetric) polynomials.
The Hilbert polynomial of a polynomial ring in k + 1 variables is the numerical polynomial
\binom{t+k}{k}