Nevanlinna–Pick interpolation explained

In complex analysis, given initial data consisting of

points

λ_1,\ldots,λ_n

in the complex unit disc

and target data consisting of

points

z_1,\ldots,z_n

, the Nevanlinna–Pick interpolation problem is to find a holomorphic function

\varphi

that interpolates the data, that is for all

i\in\{1,...,n\}

\varphi(λ_i)=z_i

,subject to the constraint

\left\vert\varphi(λ)\right\vert\le1

for all

λ\inD

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.

Background

The Nevanlinna–Pick theorem represents an

-point generalization of the Schwarz lemma. The invariant form of the Schwarz lemma states that for a holomorphic function

f:D\toD

, for all

λ_1,λ₂\inD

\left\|	f(λ₁₎-f(λ₂₎
	1-\overline{f(λ₂₎

f(λ_1)}\right|\leq\left|

	λ₁-λ₂
	1-\overline{λ₂

λ_1}\right|.

Setting

f(λ_i)=z_i

, this inequality is equivalent to the statement that the matrix given by

\begin{bmatrix}

	2
\|z
	1\|

	2
\|λ
	1\|

	1-\overline{z₁
	z

_2}{1-\overline{λ_1}λ_2}
\\[5pt]

	1-\overline{z₂
	z

_1}{1-\overline{λ_2}λ_1}&

	2
\|z
	2\|

	2
\|λ
	2\|

\end{bmatrix}\geq0,

that is the Pick matrix is positive semidefinite.

Combined with the Schwarz lemma, this leads to the observation that for

λ_1,λ_2,z_1,z₂\inD

, there exists a holomorphic function

\varphi:D\toD

such that

\varphi(λ₁₎=z₁

and

\varphi(λ_2)=z₂

if and only if the Pick matrix

\left(	1-\overline{z_j
	z

_i}{1-\overline{λ_j}λ_i}\right)_i,j\geq0.

The Nevanlinna–Pick theorem

The Nevanlinna–Pick theorem states the following. Given

λ_1,\ldots,λ_n,z_1,\ldots,z_n\inD

, there exists a holomorphic function

\varphi:D\to\overline{D

} such that

\varphi(λ_i)=z_i

if and only if the Pick matrix

\left(

	1-\overline{z_j
	z

_{i}{1-\overline{λ}_j}λ_i}

	n
\right)
	i,j=1

is positive semi-definite. Furthermore, the function

\varphi

is unique if and only if the Pick matrix has zero determinant. In this case,

\varphi

is a Blaschke product, with degree equal to the rank of the Pick matrix (except in the trivial case whereall the

z_i

's are the same).

Generalisation

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 H² is a reproducing kernel Hilbert space, and that its reproducing kernel (known as the Szegő kernel) is

K(a,b)=\left(1-b\bar{a}\right)^-1.

Because of this, the Pick matrix can be rewritten as

\left((1-z_i\overline{z_j})K(λ_j,λ_i)\right)

	N.

	i,j=1

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

f:R\toD

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

\left((1-z_i\overline{z_j})K_\tau(λ_j,λ_i)\right)

	N

	i,j=1

is a positive semi-definite matrix, for all

\tau

in the n-torus. Here, the

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.

Notes

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

D²

to the disk was solved by Jim Agler.

References

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

Notes and References

Sarason. Donald. Generalized Interpolation in
H^infty

. Trans. Amer. Math. Soc.. 1967. 127. 179–203. 10.1090/s0002-9947-1967-0208383-8. free.