Finite-rank operator: Difference between revisions

Template:More citations needed In functional analysis, a branch of mathematics, a finite-rank operator is a bounded linear operator between Banach spaces whose range is finite-dimensional.^[1]

Finite-rank operators are matrices (of finite size) transplanted to the infinite dimensional setting. As such, these operators may be described via linear algebra techniques.

From linear algebra, we know that a rectangular matrix, with complex entries, ${\displaystyle M\in {ℂ}^{n\times m}}$ has rank ${\displaystyle 1}$ if and only if ${\displaystyle M}$ is of the form

${\displaystyle M=\alpha \cdot u{v}^{*},\text{where}\Vert u\Vert =\Vert v\Vert =1\text{and}\alpha \ge 0.}$

The same argument and Riesz' lemma show that an operator ${\displaystyle T}$ on a Hilbert space ${\displaystyle H}$ is of rank ${\displaystyle 1}$ if and only if

${\displaystyle Th=\alpha ⟨h,v⟩u\text{for all}h\in H,}$

where the conditions on ${\displaystyle \alpha ,u,v}$ are the same as in the finite dimensional case.

Therefore, by induction, an operator ${\displaystyle T}$ of finite rank ${\displaystyle n}$ takes the form

${\displaystyle Th={\displaystyle \sum _{i=1}^n}{\alpha }_i⟨h,v_i⟩u_i\text{for all}h\in H,}$

where ${\displaystyle \{u_i\}}$ and ${\displaystyle \{v_i\}}$ are orthonormal bases. Notice this is essentially a restatement of singular value decomposition. This can be said to be a canonical form of finite-rank operators.

Generalizing slightly, if ${\displaystyle n}$ is now countably infinite and the sequence of positive numbers ${\displaystyle \{{\alpha }_i\}}$ accumulate only at ${\displaystyle 0}$, ${\displaystyle T}$ is then a compact operator, and one has the canonical form for compact operators.

Compact operators are trace class only if the series $\sum _i{\alpha }_i$ is convergent; a property that automatically holds for all finite-rank operators.^[2]

The family of finite-rank operators ${\displaystyle F(H)}$ on a Hilbert space ${\displaystyle H}$ form a two-sided *-ideal in ${\displaystyle L(H)}$, the algebra of bounded operators on ${\displaystyle H}$. In fact it is the minimal element among such ideals, that is, any two-sided *-ideal ${\displaystyle I}$ in ${\displaystyle L(H)}$ must contain the finite-rank operators. This is not hard to prove. Take a non-zero operator ${\displaystyle T\in I}$, then ${\displaystyle Tf=g}$ for some ${\displaystyle f,g\ne 0}$. It suffices to have that for any ${\displaystyle h,k\in H}$, the rank-1 operator ${\displaystyle S_{h,k}}$ that maps ${\displaystyle h}$ to ${\displaystyle k}$ lies in ${\displaystyle I}$. Define ${\displaystyle S_{h,f}}$ to be the rank-1 operator that maps ${\displaystyle h}$ to ${\displaystyle f}$, and ${\displaystyle S_{g,k}}$ analogously. Then

${\displaystyle S_{h,k}=S_{g,k}T{S}_{h,f},}$

which means ${\displaystyle S_{h,k}}$ is in ${\displaystyle I}$ and this verifies the claim.

Some examples of two-sided *-ideals in ${\displaystyle L(H)}$ are the trace-class, Hilbert–Schmidt operators, and compact operators. ${\displaystyle F(H)}$ is dense in all three of these ideals, in their respective norms.

Since any two-sided ideal in ${\displaystyle L(H)}$ must contain ${\displaystyle F(H)}$, the algebra ${\displaystyle L(H)}$ is simple if and only if it is finite dimensional.

A finite-rank operator ${\displaystyle T:U\to V}$ between Banach spaces is a bounded operator such that its range is finite dimensional. Just as in the Hilbert space case, it can be written in the form

${\displaystyle Th={\displaystyle \sum _{i=1}^n}⟨u_i,h⟩v_i\text{for all}h\in U,}$

where now ${\displaystyle v_i\in V}$, and ${\displaystyle u_i\in U^{\prime }}$ are bounded linear functionals on the space ${\displaystyle U}$.

A bounded linear functional is a particular case of a finite-rank operator, namely of rank one.

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