Finite-rank operator
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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 on a Hilbert space
[edit]A canonical form
[edit]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, has rank if and only if is of the form
The same argument and Riesz' lemma show that an operator on a Hilbert space is of rank if and only if
where the conditions on are the same as in the finite dimensional case.
Therefore, by induction, an operator of finite rank takes the form
where and 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 is now countably infinite and the sequence of positive numbers accumulate only at , is then a compact operator, and one has the canonical form for compact operators.
Compact operators are trace class only if the series is convergent; a property that automatically holds for all finite-rank operators.[2]
Algebraic property
[edit]The family of finite-rank operators on a Hilbert space form a two-sided *-ideal in , the algebra of bounded operators on . In fact it is the minimal element among such ideals, that is, any two-sided *-ideal in must contain the finite-rank operators. This is not hard to prove. Take a non-zero operator , then for some . It suffices to have that for any , the rank-1 operator that maps to lies in . Define to be the rank-1 operator that maps to , and analogously. Then
which means is in and this verifies the claim.
Some examples of two-sided *-ideals in are the trace-class, Hilbert–Schmidt operators, and compact operators. is dense in all three of these ideals, in their respective norms.
Since any two-sided ideal in must contain , the algebra is simple if and only if it is finite dimensional.
Finite-rank operators on a Banach space
[edit]A finite-rank operator 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
where now , and are bounded linear functionals on the space .
A bounded linear functional is a particular case of a finite-rank operator, namely of rank one.
References
[edit]- ^ "Finite Rank Operator - an overview". 2004.
- ^ Conway, John B. (1990). A course in functional analysis. New York: Springer-Verlag. pp. 267–268. ISBN 978-0-387-97245-9. OCLC 21195908.