Closed linear operator

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In functional analysis, a branch of mathematics, a closed linear operator or often a closed operator is a linear operator whose graph is closed (see closed graph property). It is a basic example of an unbounded operator.

The closed graph theorem says a linear operator between Banach spaces is a closed operator if and only if it is a bounded operator. Hence, a closed linear operator that is used in practice is typically only defined on a dense subspace of a Banach space.

Definition

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It is common in functional analysis to consider partial functions, which are functions defined on a subset of some space   A partial function   is declared with the notation   which indicates that   has prototype   (that is, its domain is   and its codomain is  )

Every partial function is, in particular, a function and so all terminology for functions can be applied to them. For instance, the graph of a partial function   is the set   However, one exception to this is the definition of "closed graph". A partial function   is said to have a closed graph if   is a closed subset of   in the product topology; importantly, note that the product space is   and not   as it was defined above for ordinary functions. In contrast, when   is considered as an ordinary function (rather than as the partial function  ), then "having a closed graph" would instead mean that   is a closed subset of   If   is a closed subset of   then it is also a closed subset of   although the converse is not guaranteed in general.

Definition: If X and Y are topological vector spaces (TVSs) then we call a linear map f : D(f) ⊆ XY a closed linear operator if its graph is closed in X × Y.

Closable maps and closures

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A linear operator   is closable in   if there exists a vector subspace   containing   and a function (resp. multifunction)   whose graph is equal to the closure of the set   in   Such an   is called a closure of   in  , is denoted by   and necessarily extends  

If   is a closable linear operator then a core or an essential domain of   is a subset   such that the closure in   of the graph of the restriction   of   to   is equal to the closure of the graph of   in   (i.e. the closure of   in   is equal to the closure of   in  ).

Examples

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A bounded operator is a closed operator. Here are examples of closed operators that are not bounded.

  • If   is a Hausdorff TVS and   is a vector topology on   that is strictly finer than   then the identity map   a closed discontinuous linear operator.[1]
  • Consider the derivative operator   where   is the Banach space of all continuous functions on an interval   If one takes its domain   to be   then   is a closed operator, which is not bounded.[2] On the other hand, if   is the space   of smooth functions scalar valued functions then   will no longer be closed, but it will be closable, with the closure being its extension defined on  

Basic properties

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The following properties are easily checked for a linear operator f : D(f) ⊆ XY between Banach spaces:

  • If A is closed then AλIdD(f) is closed where λ is a scalar and IdD(f) is the identity function;
  • If f is closed, then its kernel (or nullspace) is a closed vector subspace of X;
  • If f is closed and injective then its inverse f−1 is also closed;
  • A linear operator f admits a closure if and only if for every xX and every pair of sequences x = (xi)
    i=1
    and y = (yi)
    i=1
    in D(f) both converging to x in X, such that both f(x) = (f(xi))
    i=1
    and f(y) = (f(yi))
    i=1
    converge in Y, one has limi → ∞ fxi = limi → ∞ fyi.

References

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  1. ^ Narici & Beckenstein 2011, p. 480.
  2. ^ Kreyszig, Erwin (1978). Introductory Functional Analysis With Applications. USA: John Wiley & Sons. Inc. p. 294. ISBN 0-471-50731-8.