Dilation (operator theory)

Dilation (operator theory)

In operator theory, a dilation of an operator T on a Hilbert space H is an operator on a larger Hilbert space K , whose restriction to H is T.

More formally, let T be a bounded operator on some Hilbert space H, and H be a subspace of a larger Hilbert space H' . A bounded operator V on H' is a dilation of T if

P_H \; V | _H = T

where PH is projection on H.

V is said to be a unitary dilation (respectively, normal, isometric, etc) if V is unitary (respectively, normal, isometric, etc). T is said to be a compression of V. If an operator T has a spectral set X, we say that V is a normal boundary dilation or a normal \partial X dilation if V is a normal dilation of T and \sigma(V)\in\partial X.

Some texts impose an additional condition. Namely, that a dilation satisfy the following (calculus) property:

P_H \; f(V) | _H = f(T)

where f(T) is some specified functional calculus (for example, the polynomial or H calculus). The utility of a dilation is that it allows the "lifting" of objects associated to T to the level of V, where the lifted objects may have nicer properties. See, for example, the commutant lifting theorem.

Applications

We can show that every contraction on Hilbert spaces has a unitary dilation. A possible construction of this dilation is as follows. For a contraction T, the operator

D_T = (I - T^* T)^{\frac{1}{2}}

is positive, where the continuous functional calculus is used to define the square root. The operator DT is called the defect operator of T. Let V be the operator on

H \oplus H

defined by the matrix

V = \begin{bmatrix} T & D_{T^*}\\ \ D_T & -T^* \end{bmatrix}.

V is clearly a dilation of T. Also, T(I - T*T) = (I - TT*)T implies

T D_T = D_{T^*} T.

Using this one can show, by calculating directly, that V is unitary, therefore an unitary dilation of T. This operator V is sometimes called the Julia operator of T.

Notice that when T is a real scalar, say T = cos θ, we have

V = \begin{bmatrix} \cos \theta & \sin \theta \\ \ \sin \theta & - \cos \theta \end{bmatrix}.

which is just the unitary matrix describing rotation by θ. For this reason, the Julia operator V(T) is sometimes called the elementary rotation of T.

We note here that in the above discussion we have not required the calculus property for a dilation. Indeed, direct calculation shows the Julia operator fails to be a "degree-2" dilation in general, i.e. it need not be true that

T^2 = P_H \; V^2 | _H.

However, it can also be shown that any contraction has a unitary dilation which does have the calculus property above. This is Sz.-Nagy's dilation theorem. More generally, if \mathcal{R}(X) is a Dirichlet algebra, any operator T with X as a spectral set will have a normal \partial X dilation with this property. This generalises Sz.-Nagy's dilation theorem as all contractions have the unit disc as a spectral set.

References

  • T. Constantinescu, Schur Parameters, Dilation and Factorization Problems, Birkhauser Verlag, Vol. 82, ISBN 3-7643-5285-X, 1996.
  • Vern Paulsen, Completely Bounded Maps and Operator Algebras 2002, ISBN 0-521-81669-6

Wikimedia Foundation. 2010.

Игры ⚽ Поможем сделать НИР

Look at other dictionaries:

  • Dilation — (or dilatation) refers to an enlargement or expansion in bulk or extent, the opposite of contraction. It derives from the Latin dilatare, to spread wide . In physiology: Pupillary dilation, dilation of the pupil of the eye Cervical dilation, the… …   Wikipedia

  • Dilation (mathematics) — In mathematics, a dilation is a function fnof; from a metric space into itself that satisfies the identity:d(f(x),f(y))=rd(x,y) ,for all points x , y , where d ( x , y ) is the distance from x to y and r is some positive real number. In Euclidean …   Wikipedia

  • Dilation (metric space) — In mathematics, a dilation is a function f from a metric space into itself that satisfies the identity for all points (x,y) where d(x,y) is the distance from x to y and r is some positive real number. In Euclidean space, such a dilation is a… …   Wikipedia

  • Naimark's dilation theorem — In operator theory, Naimark s dilation theorem is a result that characterizes positive operator valued measures. It can be viewed as a consequence of Stinespring s dilation theorem. Contents 1 Note 2 Some preliminary notions 3 Naimark s theorem …   Wikipedia

  • Subnormal operator — In mathematics, especially operator theory, subnormal operators are bounded operators on a Hilbert space defined by weakening the requirements for normal operators. Some examples of subnormal operators are isometries and Toeplitz operators with… …   Wikipedia

  • Shift operator — In mathematics, and in particular functional analysis, the shift operators are examples of linear operators, important for their simplicity and natural occurrence. They are used in diverse areas, such as Hardy spaces, the theory of abelian… …   Wikipedia

  • List of mathematics articles (D) — NOTOC D D distribution D module D D Agostino s K squared test D Alembert Euler condition D Alembert operator D Alembert s formula D Alembert s paradox D Alembert s principle Dagger category Dagger compact category Dagger symmetric monoidal… …   Wikipedia

  • Stinespring factorization theorem — In mathematics, Stinespring s dilation theorem, also called Stinespring s factorization theorem, is a result from operator theory that represents any completely positive map on a C* algebra as a composition of two completely positive maps each of …   Wikipedia

  • Commutant lifting theorem — In operator theory, the commutant lifting theorem, due to Sz. Nagy and Foias, states that if T is a contraction on a Hilbert space H, U is its minimal unitary dilation acting on some Hilbert space K (which can be shown to exist by Sz. Nagy s… …   Wikipedia

  • Refinable function — In mathematics, in the area of wavelet analysis, a refinable function is a function which fulfills some kind of self similarity. A function varphi is called refinable with respect to the mask h if:varphi(x)=2cdotsum {k=0}^{N 1} h… …   Wikipedia

Share the article and excerpts

Direct link
Do a right-click on the link above
and select “Copy Link”