Nevanlinna–Pick interpolation

In complex analysis, given initial data consisting of ${\displaystyle n}$ points ${\displaystyle {\lambda }_1,\dots ,{\lambda }_n}$ in the complex unit disc ${\displaystyle \mathbb{𝔻}}$ and target data consisting of ${\displaystyle n}$ points ${\displaystyle z_1,\dots ,z_n}$ in ${\displaystyle \mathbb{𝔻}}$, the Nevanlinna–Pick interpolation problem is to find a holomorphic function ${\displaystyle \phi }$ that interpolates the data, that is for all ${\displaystyle i\in \{1,...,n\}}$,

${\displaystyle \phi ({\lambda }_i)=z_i}$,

subject to the constraint ${\displaystyle |\phi (\lambda )|\le 1}$ for all ${\displaystyle \lambda \in \mathbb{𝔻}}$.

Georg Pick and Rolf Nevanlinna solved the problem independently in 1916 and 1919 respectively, showing that an interpolating function exists if and only if a matrix defined in terms of the initial and target data is positive semi-definite.

The Nevanlinna–Pick theorem represents an ${\displaystyle n}$-point generalization of the Schwarz lemma. The invariant form of the Schwarz lemma states that for a holomorphic function ${\displaystyle f:\mathbb{𝔻}\to \mathbb{𝔻}}$, for all ${\displaystyle {\lambda }_1,{\lambda }_2\in \mathbb{𝔻}}$,

${\displaystyle \left|\frac{f({\lambda }_1)-f({\lambda }_2)}{1-\overline{f({\lambda }_2)}f({\lambda }_1)}\right|\le \left|\frac{{\lambda }_1-{\lambda }_2}{1-\overline{{\lambda }_2}{\lambda }_1}\right|.}$

Setting ${\displaystyle f({\lambda }_i)=z_i}$, this inequality is equivalent to the statement that the matrix given by

${\displaystyle \left[\begin{array}{cc}\frac{1-|z_1{|}^2}{1-|{\lambda }_1{|}^2}& \frac{1-\overline{z_1}{z}_2}{1-\overline{{\lambda }_1}{\lambda }_2}\\ \frac{1-\overline{z_2}{z}_1}{1-\overline{{\lambda }_2}{\lambda }_1}& \frac{1-|z_2{|}^2}{1-|{\lambda }_2{|}^2}\end{array}\right]\ge 0,}$

that is the Pick matrix is positive semidefinite.

Combined with the Schwarz lemma, this leads to the observation that for ${\displaystyle {\lambda }_1,{\lambda }_2,z_1,z_2\in \mathbb{𝔻}}$, there exists a holomorphic function ${\displaystyle \phi :\mathbb{𝔻}\to \mathbb{𝔻}}$ such that ${\displaystyle \phi ({\lambda }_1)=z_1}$ and ${\displaystyle \phi ({\lambda }_2)=z_2}$ if and only if the Pick matrix

${\displaystyle {\left(\frac{1-\overline{z_j}{z}_i}{1-\overline{{\lambda }_j}{\lambda }_i}\right)}_{i,j=1,2}\ge 0.}$

The Nevanlinna–Pick theorem states the following. Given ${\displaystyle {\lambda }_1,\dots ,{\lambda }_n,z_1,\dots ,z_n\in \mathbb{𝔻}}$, there exists a holomorphic function ${\displaystyle \phi :\mathbb{𝔻}\to \overline{\mathbb{𝔻}}}$ such that ${\displaystyle \phi ({\lambda }_i)=z_i}$ if and only if the Pick matrix

${\displaystyle {\left(\frac{1-\overline{z_j}{z}_i}{1-\overline{{\lambda }_j}{\lambda }_i}\right)}_{i,j=1}^n}$

is positive semi-definite. Furthermore, the function ${\displaystyle \phi }$ is unique if and only if the Pick matrix has zero determinant. In this case, ${\displaystyle \phi }$ is a Blaschke product, with degree equal to the rank of the Pick matrix (except in the trivial case where all the ${\displaystyle z_i}$'s are the same).

The generalization of the Nevanlinna–Pick theorem became an area of active research in operator theory following the work of Donald Sarason on the Sarason interpolation theorem.^[1] Sarason gave a new proof of the Nevanlinna–Pick theorem using Hilbert space methods in terms of operator contractions. Other approaches were developed in the work of L. de Branges, and B. Sz.-Nagy and C. Foias.

It can be shown that the Hardy space H ² is a reproducing kernel Hilbert space, and that its reproducing kernel (known as the Szegő kernel) is

${\displaystyle K(a,b)={(1-b\overline{a})}^{-1}.}$

Because of this, the Pick matrix can be rewritten as

${\displaystyle {((1-z_i\overline{z_j})K({\lambda }_j,{\lambda }_i))}_{i,j=1}^N.}$

This description of the solution has motivated various attempts to generalise Nevanlinna and Pick's result.

The Nevanlinna–Pick problem can be generalised to that of finding a holomorphic function ${\displaystyle f:R\to \mathbb{𝔻}}$ that interpolates a given set of data, where R is now an arbitrary region of the complex plane.

M. B. Abrahamse showed that if the boundary of R consists of finitely many analytic curves (say n + 1), then an interpolating function f exists if and only if

${\displaystyle {((1-z_i\overline{z_j})K_{\tau }({\lambda }_j,{\lambda }_i))}_{i,j=1}^N}$

is a positive semi-definite matrix, for all ${\displaystyle \tau }$ in the n-torus. Here, the ${\displaystyle K_{\tau }}$s are the reproducing kernels corresponding to a particular set of reproducing kernel Hilbert spaces, which are related to the set R. It can also be shown that f is unique if and only if one of the Pick matrices has zero determinant.

• Pick's original proof concerned functions with positive real part. Under a linear fractional Cayley transform, his result holds on maps from the disc to the disc.

• Pick–Nevanlinna interpolation was introduced into robust control by Allen Tannenbaum.

• The Pick-Nevanlinna problem for holomorphic maps from the bidisk ${\displaystyle {\mathbb{𝔻}}^2}$ to the disk was solved by Jim Agler.

• Agler, Jim; John E. McCarthy (2002). Pick Interpolation and Hilbert Function Spaces. Graduate Studies in Mathematics. AMS. ISBN 0-8218-2898-3. 
• Abrahamse, M. B. (1979). "The Pick interpolation theorem for finitely connected domains". Michigan Math. J. 26 (2): 195–203. doi:10.1307/mmj/1029002212. 
• Tannenbaum, Allen (1980). "Feedback stabilization of linear dynamical plants with uncertainty in the gain factor". Int. J. Control 32 (1): 1–16. doi:10.1080/00207178008922838. 

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