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Friedrichs extension

In functional analysis, the Friedrichs extension is a canonical self-adjoint extension of a non-negative densely defined symmetric operator. It is named after the mathematician K. Friedrichs . This extension is particularly useful in situations where an operator may fail to be essentially self-adjoint or whose essential self-adjointness is difficult to show.

An operator T is said to be non-negative iff

$\langle \xi \mid T \xi \rangle \geq 0 \quad \xi \in \operatorname{dom} T$

Example. Multiplication by a non-negative function on an L² space is a non-negative self-adjoint operator.

Example. Let U be an open set in Rⁿ. On L²(U) we consider differential operators of the form

$[T \phi](x) = -\sum_{i,j} \partial_{x_i} a_{i j}(x) \partial_{x_j} \phi(x) \quad x \in U, \phi \in \operatorname{C}_0^\infty(U),$

where the functions a_{i j} are infinitely differentiable real-valued functions on U. We consider T acting on the dense subspace

$\operatorname{C}_0^\infty(U) \subseteq L^2(U).$

If for each x the n × n matrix

$\begin{bmatrix} a_{1 1}(x) & a_{1 2}(x) & \cdots & a_{1 n}(x) \\ a_{2 1}(x) & a_{2 2} (x) & \cdots & a_{2 n}(x) \\ \vdots & \vdots & \vdots & \vdots \\ a_{n 1}(x) & a_{n 2}(x) & \cdots & a_{n n}(x) \end{bmatrix}$

is non-negative semi-definite, then T is a non-negative operator.

These operators are elliptic although in general elliptic operators may not be non-negative. They are however bounded from below.

Definition of Friedrichs extension

The definition of the Friedrichs extension is based on the theory of closed positive forms on Hilbert spaces. If T is non-negative, then

$\operatorname{Q}(\xi, \eta) = \langle \xi \mid T \eta \rangle + \langle \xi \mid \eta \rangle$

is a sesquilinear form on dom T and

$\operatorname{Q}(\xi, \xi) = \langle \xi \mid T \xi\rangle + \langle \xi \mid \xi \rangle \geq \|\xi\|^2.$

Thus Q defines an inner product on dom T. Let H₁ be the completion of dom T with respect to Q. H₁ is an abstractly defined space; for instance its elements can be represented as equivalence classes Cauchy sequences of elements of dom T. It is not obvious that all elements in H₁ can identified with elements of H. However, the following can be proved:

The canonical inclusion

$\operatorname{dom} T \rightarrow H$

extends to an injective continuous map H₁ → H. We regard H₁ as a subspace of H.

Define an operator A by

$\operatorname{dom}A = \{\xi \in H_1: \phi_\xi: \eta \mapsto \operatorname{Q}(\xi, \eta) \mbox{ is bounded linear.} \}$

In the above formula, bounded is relative to the topology on H₁ inherited from H. By the Riesz representation theorem applied to the linear functional φ_ξ extended to H, there is a unique A ξ ∈ H such that

$\operatorname{Q}(\xi,\eta) = \langle A \xi \mid \eta \rangle \quad \eta \in H_1$

Theorem. A is a non-negative self-adjoint operator such that T₁=A - I extends T.

T₁ is the Friedrichs extension of T.

Krein's theorem on non-negative self-adjoint extensions

M. G. Krein has given an elegant characterization of all non-negative self-adjoint extensions of a non-negative symmetric operator T.

If T, S are non-negative operators, write

$T \leq S$

if, and only if,

$\operatorname{dom}(S) \subseteq \operatorname{dom}(T)$

$\langle \xi \mid T \xi \rangle \leq \langle \xi \mid S \xi \rangle \quad \forall \xi \in \operatorname{dom}(S)$

Theorem. There are unique self-adjoint extensions T_min and T_max of any non-negative symmetric operator T such that

$T_{\mathrm{min}} \leq T_{\mathrm{max}},$

and every non-negative self-adjoint extension S of T is between T_min and T_max, i.e

$T_{\mathrm{min}} \leq S \leq T_{\mathrm{max}}.$

The Friedrichs extension of T is T_min.

References

N. I. Akhiezer and I. M. Glazman, Theory of Linear Operators in Hilbert Space, Pitman, 1981.

Categories: Functional analysis

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10-26-2009 08:16:03
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