Weierstrass Factorization Theorem

Theorem
Let $f$ be an entire function.

Let $0$ be a zero of $f$ of multiplicity $m \ge 0$.

Let the sequence $\sequence {a_n}$ consist of the nonzero zeroes of $f$, repeated according to multiplicity.

First Form
Let $\sequence {p_n}$ be a sequence of non-negative integers for which the series:
 * $\ds \sum_{n \mathop = 1}^\infty \size {\dfrac r {a_n} }^{1 + p_n}$

converges for every $r \in \R_{> 0}$.

Then there exists an entire function $g$ such that:
 * $\ds \map f z = z^m e^{\map g z} \prod_{n \mathop = 1}^\infty \map {E_{p_n} } {\frac z {a_n} }$

where:
 * $E_{p_n}$ are Weierstrass's elementary factors
 * the product converges locally uniformly absolutely on $\C$.

Second Form
There exists a sequence $\sequence {p_n}$ of non-negative integers and an entire function $g$ such that:
 * $\ds \map f z = z^m e^{\map g z} \prod_{n \mathop = 1}^\infty \map {E_{p_n} } {\frac z {a_n} }$

where:
 * $E_{p_n}$ are Weierstrass's elementary factors
 * the product converges locally uniformly absolutely on $\C$.

Proof
From Weierstrass Product Theorem, the function:


 * $\ds \map h z = z^m \prod_{n \mathop = 1}^\infty \map {E_{p_n} } {\frac z {a_n} }$

defines an entire function that has the same zeroes as $f$ counting multiplicity.

Thus $f / h$ is both an entire function and non-vanishing.

As $f / h$ is both holomorphic and nowhere zero there exists a holomorphic function $g$ such that:
 * $e^g = f / h$

Therefore:
 * $f = e^g h$

as desired.

Also known as
Some sources give this as the Weierstrass factor theorem or the Weierstrass infinite product theorem.

Also see

 * Hadamard Factorization Theorem, a refined version of this
 * Weierstrass Product Theorem