Runge theorem

A theorem on the possibility of polynomially approximating holomorphic functions, first proved by C. Runge (1885) (cf. also Approximation of functions of a complex variable).

Let $D$ be a simply-connected domain in the complex $z$-plane. Then any function $f$ holomorphic in $D$ can be approximated uniformly on compact sets inside $D$ by polynomials in $z$. More precisely, for any compact set $K\subset D$ and $\epsilon>0$ there is a polynomial $p(z)$ with complex coefficients such that $|f(z)-p(z)|<\epsilon$ for all $z\in K$.

In other words: Any function $f$ holomorphic in a simply-connected domain $D\subset\mathbf C$ can be represented as a series of polynomials in $z$ converging absolutely and uniformly to $f$ on compact sets inside $D$.

An equivalent statement of Runge's theorem: Let $K$ be a compact set in $\mathbf C$ with connected complement $\mathbf C\setminus K$; then any function holomorphic in a neighbourhood of $K$ can be approximated uniformly on $K$ by polynomials in $z$. In this formulation, Runge's theorem is a special case of Mergelyan's theorem (cf. Mergelyan theorem).

The following theorem on rational approximation is also called Runge's theorem: Any function $f$ holomorphic in a domain $D\subset\mathbf C$ can be uniformly approximated on compact sets inside $D$ by rational functions with poles outside $D$.

Runge's theorem has many applications in the theory of functions of a complex variable and in functional analysis. A theorem analogous to Runge's theorem is valid for non-compact Riemann surfaces. An extension of Runge's theorem to functions of several complex variables is the Oka–Weil theorem (see Oka theorems).

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Comments

For more about Runge's theorem and its generalizations, such as Walsh' theorem, the Keldysh theorem, the Lavrent'ev theorem, see [a6], [a1], Chapt. VIII, and [a3], Chapt. III, for the case of the complex plane; [a2], Sect. 25, for the case of Riemann surfaces; and [a4], Sect. 7, for the case of several complex variables.

References