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{{otheruses4|the general mathematical result|the application to time series analysis|Wold's theorem}}
In [[operator theory]], a discipline within mathematics, the '''Wold decomposition''', named after [[Herman Wold]], or '''Wold–von Neumann decomposition''', after Wold and [[John von Neumann]], is a classification theorem for [[isometry|isometric linear operator]]s on a given [[Hilbert space]]. It states that every isometry is a direct sums of copies of the [[unilateral shift]] and a [[unitary operator]].
 
In [[time series analysis]], the theorem implies that any [[Stationary process|stationary]] discrete-time [[stochastic process]] can be decomposed into a pair of uncorrelated processes, one deterministic, and the other being a [[moving average process]].
 
== Details ==
 
Let ''H'' be a Hilbert space, ''L''(''H'') be the bounded operators on ''H'', and ''V'' ∈ ''L''(''H'') be an isometry. The '''Wold decomposition''' states that every isometry ''V'' takes the form
 
:<math>V = (\oplus_{\alpha \in A} S) \oplus U</math>
 
for some index set ''A'', where ''S'' in the [[unilateral shift]] on a Hilbert space ''H<sub>α</sub>'', and ''U'' is an unitary operator (possible vacuous). The family {''H<sub>α</sub>''} consists of isomorphic Hilbert spaces.
 
A proof can be sketched as follows. Successive applications of ''V'' give a descending sequences of copies of ''H'' isomorphically embedded in itself:
 
:<math>H = H \supset V(H) \supset V^2 (H) \supset \cdots = H_0 \supset H_1 \supset H_2 \supset \cdots, </math>
 
where ''V''(''H'') denotes the range of ''V''. The above defined <math>H_i = V^i(H)</math>. If one defines
 
:<math>M_i = H_i \ominus H_{i+1} = V^i (H \ominus V(H)) \quad \text{for} \quad i \geq 0 \;,</math>
 
then
 
:<math>H = (\oplus_{i \geq 0} M_i) \oplus (\cap_{i \geq 0} H_i) = K_1 \oplus K_2.</math>
 
It is clear that ''K''<sub>1</sub> and ''K''<sub>2</sub> are invariant subspaces of ''V''.
 
So ''V''(''K''<sub>2</sub>) = ''K''<sub>2</sub>. In other words, ''V'' restricted to ''K''<sub>2</sub> is a surjective isometry, i.e. an unitary operator ''U''.
 
Furthermore, each ''M<sub>i</sub>'' is isomorphic to another, with ''V'' being an isomorphism between ''M<sub>i</sub>'' and ''M''<sub>''i''+1</sub>: ''V'' "shifts" ''M<sub>i</sub>'' to ''M''<sub>''i''+1</sub>. Suppose the dimension of each ''M<sub>i</sub>'' is some cardinal number ''α''. We see  that ''K''<sub>1</sub> can be written as a direct sum Hilbert spaces
 
:<math>K_1 = \oplus H_{\alpha}</math>
 
where each ''H<sub>α</sub>'' is an invariant subspaces of ''V'' and ''V'' restricted to each ''H<sub>α</sub>'' is the unilateral shift ''S''. Therefore
 
:<math>V = V \vert_{K_1} \oplus V\vert_{K_2} = (\oplus_{\alpha \in A} S) \oplus U,</math>
 
which is a Wold decomposition of ''V''.
 
=== Remarks ===
 
It is immediate from the Wold decomposition that the [[spectrum (functional analysis)|spectrum]] of any proper, i.e. non-unitary, isometry is the unit disk in the complex plane.
 
An isometry ''V'' is said to be '''pure''' if, in the notation of the above proof, ∩<sub>''i''≥0</sub> ''H''<sub>''i''</sub> = {0}. The '''multiplicity''' of a pure isometry ''V'' is the dimension of the kernel of ''V*'', i.e. the cardinality of the index set ''A'' in the Wold decomposition of ''V''. In other words, a pure isometry of multiplicity ''N'' takes the form
 
:<math>V = \oplus_{1 \le \alpha \le N} S .</math>
 
In this terminology, the Wold decomposition expresses an isometry as a direct sum of a pure isometry and an unitary.
 
A subspace ''M'' is called a [[wandering set|wandering subspace]] of ''V'' if ''V''<sup>''n''</sup>(''M'') ⊥ ''V''<sup>''m''</sup>(''M'') for all ''n'' ≠ ''m''. In particular, each ''M''<sub>''i''</sub> defined above is a wandering subspace of&nbsp;''V''.
 
== A sequence of isometries ==
{{Expand section|date=June 2008}}
The decomposition above can be generalized slightly to a sequence of isometries, indexed by the integers.
 
== The C*-algebra generated by an isometry ==
 
Consider an isometry ''V'' ∈ ''L''(''H''). Denote by ''C*''(''V'') the [[C*-algebra]] generated by ''V'', i.e. ''C*''(''V'') is the norm closure of polynomials in ''V'' and ''V*''. The Wold decomposition can be applied to characterize ''C*''(''V'').
 
Let ''C''('''T''') be the continuous functions on the unit circle '''T'''. We recall that the C*-algebra ''C*''(''S'') generated by the unilateral shift ''S'' takes the following form
 
:''C*''(''S'') = {''T''<sub>''f''</sub> + ''K'' | ''T''<sub>''f''</sub> is a [[Toeplitz operator]] with continuous symbol ''f'' &isin; ''C''('''T''') and ''K'' is a [[compact operator on Hilbert space|compact operator]]}.
 
In this identification, ''S'' = ''T''<sub>''z''</sub> where ''z'' is the identity function in ''C''('''T'''). The algebra ''C*''(''S'') is called the [[Toeplitz algebra]].  
 
'''Theorem (Coburn)''' ''C*''(''V'') is isomorphic to the Toeplitz algebra and ''V'' is the isomorphic image of ''T<sub>z</sub>''.
 
The proof hinges on the connections with ''C''('''T'''), in the description of the Toeplitz algebra and that the spectrum of an unitary operator is contained in the circle '''T'''.
 
The following properties of the Toeplitz algebra will be needed:
 
#<math>T_f + T_g = T_{f+g}.\,</math>
#<math> T_f ^* = T_{{\bar f}} .</math>
#The semicommutator <math>T_fT_g - T_{fg} \,</math> is compact.
 
The Wold decomposition says that ''V'' is the direct sum of copies of ''T''<sub>''z''</sub> and then some unitary ''U'':
 
:<math>V = (\oplus_{\alpha \in A} T_z) \oplus U.</math>
 
So we invoke the [[continuous functional calculus]] ''f'' → ''f''(''U''), and define
 
:<math>
\Phi : C^*(S) \rightarrow C^*(V) \quad \text{by} \quad \Phi(T_f + K) = \oplus_{\alpha \in A} (T_f + K) \oplus f(U).
</math>
 
One can now verify Φ is an isomorphism that maps the unilateral shift to ''V'':
 
By property 1 above, Φ is linear. The map Φ is injective because ''T<sub>f</sub>'' is not compact for any non-zero ''f'' ∈ ''C''('''T''') and thus ''T<sub>f</sub>'' + ''K'' = 0 implies ''f'' = 0. Since the range of Φ is a C*-algebra, Φ is surjective by the minimality of ''C*''(''V''). Property 2 and the continuous functional calculus ensure that Φ preserves the *-operation. Finally, the semicommutator property shows that Φ is multiplicative. Therefore the theorem holds.
 
== References ==
 
*L. Coburn, The C*-algebra of an isometry, ''Bull. Amer. Math. Soc.'' '''73''', 1967, 722&ndash;726.
 
*T. Constantinescu, ''Schur Parameters, Dilation and Factorization Problems'', Birkhauser Verlag, Vol. 82, 1996.
 
*R.G. Douglas, ''Banach Algebra Techniques in Operator Theory'', Academic Press, 1972.
 
*Marvin Rosenblum and James Rovnyak, ''Hardy Classes and Operator Theory'', Oxford University Press, 1985.
 
[[Category:Operator theory]]
[[Category:Invariant subspaces]]
[[Category:Functional analysis]]
[[Category:C*-algebras]]
[[Category:Theorems in functional analysis]]
 
[[de:Shiftoperator#Wold-Zerlegung]]

Revision as of 18:26, 31 January 2014

Template:Otheruses4 In operator theory, a discipline within mathematics, the Wold decomposition, named after Herman Wold, or Wold–von Neumann decomposition, after Wold and John von Neumann, is a classification theorem for isometric linear operators on a given Hilbert space. It states that every isometry is a direct sums of copies of the unilateral shift and a unitary operator.

In time series analysis, the theorem implies that any stationary discrete-time stochastic process can be decomposed into a pair of uncorrelated processes, one deterministic, and the other being a moving average process.

Details

Let H be a Hilbert space, L(H) be the bounded operators on H, and VL(H) be an isometry. The Wold decomposition states that every isometry V takes the form

V=(αAS)U

for some index set A, where S in the unilateral shift on a Hilbert space Hα, and U is an unitary operator (possible vacuous). The family {Hα} consists of isomorphic Hilbert spaces.

A proof can be sketched as follows. Successive applications of V give a descending sequences of copies of H isomorphically embedded in itself:

H=HV(H)V2(H)=H0H1H2,

where V(H) denotes the range of V. The above defined Hi=Vi(H). If one defines

Mi=HiHi+1=Vi(HV(H))fori0,

then

H=(i0Mi)(i0Hi)=K1K2.

It is clear that K1 and K2 are invariant subspaces of V.

So V(K2) = K2. In other words, V restricted to K2 is a surjective isometry, i.e. an unitary operator U.

Furthermore, each Mi is isomorphic to another, with V being an isomorphism between Mi and Mi+1: V "shifts" Mi to Mi+1. Suppose the dimension of each Mi is some cardinal number α. We see that K1 can be written as a direct sum Hilbert spaces

K1=Hα

where each Hα is an invariant subspaces of V and V restricted to each Hα is the unilateral shift S. Therefore

V=V|K1V|K2=(αAS)U,

which is a Wold decomposition of V.

Remarks

It is immediate from the Wold decomposition that the spectrum of any proper, i.e. non-unitary, isometry is the unit disk in the complex plane.

An isometry V is said to be pure if, in the notation of the above proof, ∩i≥0 Hi = {0}. The multiplicity of a pure isometry V is the dimension of the kernel of V*, i.e. the cardinality of the index set A in the Wold decomposition of V. In other words, a pure isometry of multiplicity N takes the form

V=1αNS.

In this terminology, the Wold decomposition expresses an isometry as a direct sum of a pure isometry and an unitary.

A subspace M is called a wandering subspace of V if Vn(M) ⊥ Vm(M) for all nm. In particular, each Mi defined above is a wandering subspace of V.

A sequence of isometries

Template:Expand section The decomposition above can be generalized slightly to a sequence of isometries, indexed by the integers.

The C*-algebra generated by an isometry

Consider an isometry VL(H). Denote by C*(V) the C*-algebra generated by V, i.e. C*(V) is the norm closure of polynomials in V and V*. The Wold decomposition can be applied to characterize C*(V).

Let C(T) be the continuous functions on the unit circle T. We recall that the C*-algebra C*(S) generated by the unilateral shift S takes the following form

C*(S) = {Tf + K | Tf is a Toeplitz operator with continuous symbol fC(T) and K is a compact operator}.

In this identification, S = Tz where z is the identity function in C(T). The algebra C*(S) is called the Toeplitz algebra.

Theorem (Coburn) C*(V) is isomorphic to the Toeplitz algebra and V is the isomorphic image of Tz.

The proof hinges on the connections with C(T), in the description of the Toeplitz algebra and that the spectrum of an unitary operator is contained in the circle T.

The following properties of the Toeplitz algebra will be needed:

  1. Tf+Tg=Tf+g.
  2. Tf*=Tf¯.
  3. The semicommutator TfTgTfg is compact.

The Wold decomposition says that V is the direct sum of copies of Tz and then some unitary U:

V=(αATz)U.

So we invoke the continuous functional calculus ff(U), and define

Φ:C*(S)C*(V)byΦ(Tf+K)=αA(Tf+K)f(U).

One can now verify Φ is an isomorphism that maps the unilateral shift to V:

By property 1 above, Φ is linear. The map Φ is injective because Tf is not compact for any non-zero fC(T) and thus Tf + K = 0 implies f = 0. Since the range of Φ is a C*-algebra, Φ is surjective by the minimality of C*(V). Property 2 and the continuous functional calculus ensure that Φ preserves the *-operation. Finally, the semicommutator property shows that Φ is multiplicative. Therefore the theorem holds.

References

  • L. Coburn, The C*-algebra of an isometry, Bull. Amer. Math. Soc. 73, 1967, 722–726.
  • T. Constantinescu, Schur Parameters, Dilation and Factorization Problems, Birkhauser Verlag, Vol. 82, 1996.
  • R.G. Douglas, Banach Algebra Techniques in Operator Theory, Academic Press, 1972.
  • Marvin Rosenblum and James Rovnyak, Hardy Classes and Operator Theory, Oxford University Press, 1985.

de:Shiftoperator#Wold-Zerlegung