Given a Hilbert space with a tensor product structure a product numerical range is defined as a numerical range with respect to the subset of product vectors. In some situations, especially in the context of quantum mechanics product numerical range is known as local numerical range
Let
X
N
l{H}N
Λ(X)
λ
{|\psi\rangle}\in l{H}N
||\psi||=1
{\langle\psi|}X{|\psi\rangle}= λ
An analogous notion can be defined for operators acting on a composite Hilbert space with a tensor product structure. Consider first a bi - partite Hilbert space,
l{H}N=l{H}K ⊗ l{H}M,
N=KM
Let
X
Λ ⊗ \left(X\right)
X
l{H}N
Λ ⊗ \left(X\right)=\left\{{\langle\psiA ⊗ \psiB|}X{|\psiA ⊗ \psiB\rangle}:{|\psiA\rangle}\inl{H}K,{|\psiB\rangle}\inl{H}M\right\},
{|\psiA\rangle}\inl{H}K
{|\psiB\rangle}\inl{H}M
Let
l{H}N=l{H}K ⊗ l{H}M
r ⊗ (X)
X
r ⊗ (X)=max\{|z|:z\inΛ ⊗ \left(X\right)\}.
The notion of numerical range of a given operator, also called "field of values", has been extensively studied during the last few decades and its usefulness in quantum theory has been emphasized. Several generalizations of numerical range are known. In particular, Marcus introduced the notion of ’’’decomposable numerical range’’’, the properties of which are a subject of considerable interest.
The product numerical range can be considered as a particular case of the decomposable numerical range defined for operators acting on a tensor product Hilbert space. This notion may also be considered as a numerical range relative to the proper subgroup
U(K) x U(M)
U(KM)
It is not difficult to establish the basic properties of the product numerical range which are independent of the partition of the Hilbert space and of the structure of the operator. We list them below leaving some simple items without a proof.
Topological facts concerning product numerical range for general operators.
A,B\inMn
Λ ⊗ \left(A+B\right)\subsetΛ ⊗ \left(A\right)+Λ ⊗ \left(B\right).
A\inMn
\alpha\inC
Λ ⊗ \left({A+\alphaI
A\inMn
\alpha\inC
Λ ⊗ \left({\alphaA}\right)=\alphaΛ ⊗ \left({A}\right).
A\inMm x
Λ ⊗ \left({(U ⊗ V)A(U ⊗ V)\dagger}\right)=Λ ⊗ \left({A}\right),
U\inMm
V\inMn
A\inMm
B\inMn
Λ(A ⊗ B)=Co(Λ ⊗ \left({A ⊗ B}\right)).
eiA
\theta\in[0,2\pi)
Λ(A ⊗ B)=Λ ⊗ \left({A ⊗ B}\right).
| H(A)= | 1 |
| 2 |
(A+A\dagger)
| S(A)= | 1 |
| 2 |
(A-A\dagger)
A\inMn
Λ ⊗ \left({H(A)}\right)=Re Λ ⊗ \left({A}\right)
Λ ⊗ \left({S(A)}\right)=iIm Λ ⊗ \left({A}\right).
The product numerical range does not need to be convex. Consider the following simple example. Let
A= \left(\begin{array}{cc} 1&0\\ 0&0 \end{array} \right) ⊗ \left(\begin{array}{cc} 1&0\\ 0&0 \end{array} \right) +i \left(\begin{array}{cc} 0&0\\ 0&1 \end{array} \right) ⊗ \left(\begin{array}{cc} 0&0\\ 0&1 \end{array} \right).
Matrix
A
0,1,i
1\inΛ ⊗ \left({A}\right)
i\inΛ ⊗ \left({A}\right)
(1+i)/2\not\inΛ ⊗ \left({A}\right)
Λ ⊗ \left({A}\right)=\left\{x+yi:0\leqx,0\leqy,\sqrt{x}+\sqrt{y}\leq1\right\}.
Product numerical range of matrix
A
Product numerical range forms a nonempty set for a general operator. In particular it contains the barycenter of the spectrum.
Product numerical range of
A\inMK x
| 1 | |
| KM |
{tr
Product numerical radius is a vector norm on matrices, but it is not a matrix norm. Product numerical radius is invariant with respect to local unitaries, which have the tensor product structure.