Schur functions. J. Rovnyak and H. S. V. de Snoo

Schur functions J. Rovnyak and H. S. V. de Snoo The Schur class in complex analysis is the set of holomorphic functions S(z) which are defined and satisfy S(z) 1 on the unit disk D = {z : z < 1} in the complex plane. The Schur class arises in diverse areas of classical analysis and operator theory, and it has applications in linear system theory and mathematical engineering. The Schur algorithm [15] is an iterative construction that associates a sequence of complex numbers {γ n } n=0 with a given function S(z) in the Schur class. The numbers are defined in terms of a sequence of Schur functions which is constructed recursively by setting S 0 (z) = S(z) and S n+1 (z) = 1 z S n (z) S n (0) 1 S n (0)S n (z), n 0. If S k (0) = 1 for some k, S k (z) reduces to a constant and we set S m (z) 0 for all m > k. The sequence γ n = S n (0), n 0, thus consists of numbers of modulus at most one, and if some term of the sequence has unit modulus, all subsequent terms vanish; the numbers {γ n } n=0 are the Schur parameters of S(z). Every sequence of complex numbers of modulus at most one, having the property that if some term has unit modulus then all subsequent terms vanish, occurs as the Schur parameters of a unique function in the Schur class. The Schur class plays a prominent role in classical moment and interpolation problems. One of the best known is the Schur problem, or Carathéodory- Fejér problem: Find a Schur function S(z) whose first n Taylor coefficients coincide with given numbers S 0,..., S n 1. The Schur algorithm provides a means to describe all such functions because the first n Schur parameters of a Schur function S(z) depend only on the first n Taylor coefficients of S(z). A solution exists if and only if the matrix S 0 0 0 0 S 1 S 0 0 0 S 2 S 1 S 0 0 S n 1 S n 2 S n 3 S 0 has norm at most one as an operator on C n in the Euclidean metric. Similar results hold for the Nevanlinna-Pick problem: Find a Schur function S(z) such that z j = S(w j ), j = 1,...,n, where w 1,...,w n are given points in the 1

unit disk and z 1,..., z n are complex numbers. A solution to the Nevanlinna-Pick problem exists if and only if the matrix { } n 1 zj z k 1 w j w k j,k=1 is nonnegative as an operator on C n in the Euclidean metric. For example, see [1, Chapter 3]. Many such classical problems are subsumed in abstract operator problems. There are several approaches in common use, and a comprehensive description of the subject is beyond the scope of this review. To describe one approach, let T be multiplication by a Schur function S(z) on the Hardy class H 2 for the unit disk [5], and let U be multiplication by z on H 2. Then T is a contraction which commutes with U, and every contraction on H 2 which commutes with U has this form for some Schur function S(z). The commutation relation TU = UT is preserved under compressions of T and U to certain subspaces of H 2. Let H be an invariant subspace for U, and let A = PT H and X = PU H, where P is the projection of H 2 onto H. Then AX = XA. The generalized interpolation theorem of Sarason [13] asserts that every contraction A on H which commutes with X has this form and is therefore associated with some Schur function S(z). Particular choices of the invariant subspace H lead to solutions to the Schur and Nevanlinna-Pick problems. The generalized interpolation theorem has an abstract extension in the commutant lifting theorem [16, p. 66], which extends the conclusion to arbitrary Hilbert space contraction operators A L(H 1, H 2 ), X 1 L(H 1 ), and X 2 L(H 2 ) which are connected by a commutation relation AX 1 = X 2 A. In turn, the commutant lifting theorem is part of a broader theory of extensions and completions of Hilbert space operators [7], which is motivated in part by connections with linear system theory and mathematical engineering [8]. In such generalizations, scalar-valued functions are often replaced by matrix- or operator-valued functions. In tangential interpolation problems, only certain components of the data are specified. The approach of Potapov [11] has diverse applications, as discussed, for example, in [12]. The Ball, Gohberg, and Rodman account [3] emphasizes realization theory. The book review by Dym [6] gives an overview of operator methods in interpolation theory. Schur functions arise in operator theory in other ways, such as invariant subspace theory and its generalizations. For any Schur function S(z), the kernel K S (w, z) = [1 S(z)S(w)]/(1 z w) is nonnegative on the unit disk in the sense that n i,j=1 c ik S (w j, w i )c j 0, for all w 1,..., w n D, c 1,..., c n C, and n 1. Therefore K S (w, z) is the reproducing kernel for a Hilbert space H(S) of holomorphic functions on D. The transformations T : h(z) [h(z) h(0)]/z on H(S) to H(S), F : c [S(z) S(0)]c/z on C to H(S), G : h(z) h(0) on H(S) to C, H : c S(0)c on C to C, 2

are well defined, and the colligation V = ( ) T F G H is coisometric on H(S) C, that is, V V = 1. The characteristic function of the colligation is S(z): S(z)c = Hc + zg(1 zt) 1 Fc, c C. The class of Hilbert space operators which are unitarily equivalent to a transformation T which arises in this way from some Schur function can be characterized [4, p. 39]. Schur functions thus encode structural information for contraction operators. For example, the study of invariant subspaces is intimately involved in factorizations S(z) = S 1 (z)s 2 (z) of a Schur function into a product of two Schur functions. The transformation T is an example of a canonical model, that is, a concrete operator which is unitarily equivalent to an abstract operator of some prescribed type. A canonical model due to Sz.-Nagy and Foiaş is given in [16]; see [10] for a general notion of canonical model and operator-theoretic applications. Function-theoretic properties of a Schur function S(z), in turn, may be studied with the aid of model operators [14]. More generally, a meromorphic function S(z), holomorphic in a subregion Ω of D which contains the origin, is a generalized Schur function with κ negative squares if the kernel K S (w, z) has κ negative squares, that is, if every matrix ( c i K S (w j, w i )c j ) n i,j=1, where w 1,..., w n Ω, c 1,..., c n C, and n 1, always has at most κ negative eigenvalues, and at least one such matrix has exactly κ negative eigenvalues [9]. A space H(S) having reproducing kernel K S (w, z) exists now as a Pontryagin space. Transformations T, F, G, H can be defined as before, giving rise to a coisometric colligation V in the same way. The main results of the Hilbert space theory have extensions to this situation [2]. The indefinite theory has new elements. An example is the existence of a κ-dimensional nonpositive invariant subspace for the contraction T on H(S). The existence of such a subspace leads to the Kreĭn-Langer factorization S(z) = B(z) 1 S 0 (z) for the generalized Schur function S(z). Here B(z) is a Blaschke product having κ factors and S 0 (z) belongs to the classical Schur class and is nonvanishing at the zeros of B(z). To say that B(z) is a Blaschke product of κ factors means that it has the form B(z) = C κ j=1 z α j 1 ᾱ j z, where α 1,..., α κ are (not necessarily distinct) points of D and C is a constant of unit modulus [5]. The case κ = 0 is included by interpreting an empty product as one. Conversely, every function of the form S(z) = B(z) 1 S 0 (z) with B(z) and S(z) as above is a generalized Schur function with κ negative squares. 3

References [1] N. I. Akhiezer, The classical moment problem, Hafner, New York, 1965. [2] D. Alpay, A. Dijksma, J. Rovnyak, and H. S. V. de Snoo, Reproducing kernel Pontryagin spaces, Holomorphic spaces (Berkeley, CA, 1995), Cambridge Univ. Press, Cambridge, 1998, pp. 425 444. [3] J. A. Ball, I. Gohberg, and L. Rodman, Interpolation of rational matrix functions, Oper. Theory: Adv. Appl., vol. 45, Birkhäuser, Basel, 1990. [4] L. de Branges and J. Rovnyak, Square summable power series, Holt, Rinehart and Winston, New York, 1966. [5] P. L. Duren, Theory of H p spaces, Academic Press, New York, 1970. [6] H. Dym, The commutant lifting approach to interpolation problems, by Ciprian Foias and Arthur E. Frazho (book review), Bull. Amer. Math. Soc. 31 (1994), 125 140. [7] C. Foias, A. E. Frazho, I. Gohberg, and M. A. Kaashoek, Metric constrained interpolation, commutant lifting and systems, Oper. Theory: Adv. Appl., vol. 100, Birkhäuser, Basel, 1998. [8] T. Kailath, A theorem of I. Schur and its impact on modern signal processing, I. Schur methods in operator theory and signal processing, Oper. Theory: Adv. Appl., vol. 18, Birkhäuser, Basel, 1986, pp. 9 30. [9] M. G. Kreĭn and H. Langer, Über einige Fortsetzungsprobleme, die eng mit der Theorie hermitescher Operatoren im Raume π κ zusammenhängen. I. Einige Funktionenklassen und ihre Darstellungen, Math. Nachr. 77 (1977), 187 236. [10] N. Nikolski and V. Vasyunin, Elements of spectral theory in terms of the free function model. I. Basic constructions, Holomorphic spaces (Berkeley, CA, 1995), Cambridge Univ. Press, Cambridge, 1998, pp. 211 302. [11] V. P. Potapov, Collected papers, Hokkaido University Research Institute of Applied Electricity, Division of Applied Mathematics, Sapporo, 1982, Translated from the Russian and edited by T. Ando. [12] L. A. Sakhnovich, Interpolation theory and its applications, Kluwer Academic Publishers, Dordrecht, 1997. [13] D. Sarason, Generalized interpolation in H, Trans. Amer. Math. Soc. 127 (1967), 179 203. [14], Sub-Hardy Hilbert spaces in the unit disk, Wiley, New York, 1994. 4

[15] I. Schur, Über Potenzreihen, die im Innern des Einheitskreises beschränkt sind. I. II, J. Reine Angew. Math. 147 (1917), 205 232 (Part I), and 148 (1918), 122 145 (Part II); Gesammelte Abhandlungen, vol. II, nos. 29, 30; English translation in I. Schur methods in operator theory and signal processing, Oper. Theory Adv. Appl., vol. 18, Birkhäuser, Basel and Boston, 1986. [16] B. Sz.-Nagy and C. Foiaş, Harmonic analysis of operators on Hilbert space, North-Holland Publishing Co., Amsterdam, 1970. 5