Schatten norm explained

In mathematics, specifically functional analysis, the Schatten norm (or Schatten–von-Neumann norm) arises as a generalization of p-integrability similar to the trace class norm and the Hilbert–Schmidt norm.

Definition

Let

H1

,

H2

be Hilbert spaces, and

T

a (linear) bounded operator from

H1

to

H2

. For

p\in[1,infty)

, define the Schatten p-norm of

T

as

\|T\|p=[\operatorname{Tr}(|T|p)]1/p,

where

|T|:=\sqrt{(T*T)}

, using the operator square root.

If

T

is compact and

H1,H2

are separable, then

\|T\|p:=(\sumn\ge

1/p
s
n(T))

for

s1(T)\ges2(T)\ge\gesn(T)\ge\ge0

the singular values of

T

, i.e. the eigenvalues of the Hermitian operator

|T|:=\sqrt{(T*T)}

.

Properties

In the following we formally extend the range of

p

to

[1,infty]

with the convention that

\|\|infty

is the operator norm. The dual index to

p=infty

is then

q=1

.

U

and

V

and

p\in[1,infty]

,

\|UTV\|p=\|T\|p.

p\in[1,infty]

and

q

such that
1
p

+

1
q

=1

, and operators

S\inl{L}(H2,H3),T\inl{L}(H1,H2)

defined between Hilbert spaces

H1,H2,

and

H3

respectively,

\|ST\|1\leq\|S\|p\|T\|q.

If

p,q,r\in[1,infty]

satisfy

\tfrac{1}{p}+\tfrac{1}{q}=\tfrac{1}{r}

, then we have

\|ST\|r\leq\|S\|p\|T\|q

. The latter version of Hölder's inequality is proven in higher generality (for noncommutative

Lp

spaces instead of Schatten-p classes) in.[1] (For matrices the latter result is found in [2] .)

p\in[1,infty]

and operators

S\inl{L}(H2,H3),T\inl{L}(H1,H2)

defined between Hilbert spaces

H1,H2,

and

H3

respectively,

\|ST\|p\leq\|S\|p\|T\|p.

1\leqp\leqp'\leqinfty

,

\|T\|1\geq\|T\|p\geq\|T\|p'\geq\|T\|infty.

H1,H2

be finite-dimensional Hilbert spaces,

p\in[1,infty]

and

q

such that
1
p

+

1
q

=1

, then

\|S\|p=\sup\lbrace|\langleS,T\rangle|\mid\|T\|q=1\rbrace,

where

\langleS,T\rangle=\operatorname{tr}(S*T)

denotes the Hilbert–Schmidt inner product.

(ek)k,(fk')k'

be two orthonormal basis of the Hilbert spaces

H1,H2

, then for

p=1

\|T\|1\leq\sumk,k'\left|Tk,k'\right|.

Remarks

Notice that

\|\|2

is the Hilbert–Schmidt norm (see Hilbert–Schmidt operator),

\|\|1

is the trace class norm (see trace class), and

\|\|infty

is the operator norm (see operator norm).

For

p\in(0,1)

the function

\|\|p

is an example of a quasinorm.

An operator which has a finite Schatten norm is called a Schatten class operator and the space of such operators is denoted by

Sp(H1,H2)

. With this norm,

Sp(H1,H2)

is a Banach space, and a Hilbert space for p = 2.

Observe that

Sp(H1,H2)\subseteql{K}(H1,H2)

, the algebra of compact operators. This follows from the fact that if the sum is finite the spectrum will be finite or countable with the origin as limit point, and hence a compact operator (see compact operator on Hilbert space).

The case p = 1 is often referred to as the nuclear norm (also known as the trace norm, or the Ky Fan n-norm[3])

See also

Matrix norms

References

Notes and References

  1. Fack . Thierry . Kosaki . Hideki . Generalized

    s

    -numbers of

    \tau

    -measurable operators.     . Pacific Journal of Mathematics . 1986 . 123 . 2 .
  2. 10.1007/BF01231769. Sharp uniform convexity and smoothness inequalities for trace norms. Inventiones Mathematicae. 115. 463–482. 1994. Ball. Keith. Carlen. Eric A.. Lieb. Elliott H.. 1994InMat.115..463B . 189831705.
  3. Fan. Ky.. 1951. Maximum properties and inequalities for the eigenvalues of completely continuous operators. Proceedings of the National Academy of Sciences of the United States of America. 37. 11. 760–766. 10.1073/pnas.37.11.760. 1063464. 16578416. 1951PNAS...37..760F. free.

This article is licensed under the GNU Free Documentation License. It uses material from the Wikipedia article "Schatten norm".

Except where otherwise indicated, Everything.Explained.Today is © Copyright 2009-2025, A B Cryer, All Rights Reserved. Cookie policy.