projections as noncommutative characteristic functions

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  Just like projections, characteristic functions satisfy: ${\chi }_A^2={\chi }_A$. Thus, both characteristic functions and projections are idempotents.

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  Characteristic functions are functions (meaning they take only positive or zero values), just like projections are positive operators.

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  Characteristic functions take only the values $0$ and $1$. The spectrum of a projection is contained in $\{0,1\}$. Notice that the spectrum of a normal operator consists precisely of the values of the complex valued function associated with it (using the Gelfand-Naimark theorem and/or the continuous functional calculus).

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  A partial ordering can be defined on the set of characteristic functions by saying

  $${\chi }_A\le {\chi }_B⟺A\subseteq B\text{, or equivalently,}{\chi }_A\le {\chi }_B⟺{\chi }_B-{\chi }_A\text{is a positive function}.$$

  Analogously, a partial ordering can be defined on the set of projections by saying

  $$P\le Q⟺\mathrm{Ran}(P)\subseteq \mathrm{Ran}(Q)\text{, or equivalently,}P\le Q⟺Q-P\text{is a positive operator}.$$

  where $\mathrm{Ran}(P)$ denotes the range of the operator $P$.

The above observations could all be easily derived from the general fact we describe next:

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  Consider the Banach algebra $L^{\mathrm{\infty }}(X,\mu )$. Functions $f\in L^{\mathrm{\infty }}(X,\mu )$ can be seen as multiplication operators in the Hilbert space $L^2(X,\mu )$. Thus, $L^{\mathrm{\infty }}(X,\mu )$ can be seen as a closed subalgebra of $B(L^2(X,\mu ))$ (it is in fact a von Neumann algebra).

  Characteristic functions in $L^{\mathrm{\infty }}(X,\mu )$ are exactly the projections of this subalgebra.

The next key observation explores the similarities between some facts about measure theory and the spectral theorem of self-adjoint (or normal) operators.

It is a well known fact from measure theory that a continuous function $f:X⟶ℝ$ can be approximated by linear combinations of characteristic functions. With some additional effort it can be seen that, in fact, each continuous function $f$ is a (vector valued) integral of characteristic functions

$$f={\int }_{X}f𝑑\chi$$

where $\chi$ is the vector measure of characteristic functions $\chi (A):={\chi }_A$.

An analogous phenomenon in the spectral theory of normal operators. Notice (as pointed earlier) that the $C^{*}$-algebra (http://planetmath.org/CAlgebra) theory allows one to see a normal operator as a continuous function. With this in mind, the spectral theorem of normal operators can be seen as an analog of the previous measure theoretic construction. Recall that the spectral theorem that a normal operator $N$ can be approximated by linear combinations of projections and can, in fact, be given by a (vector valued) integral of projections:

$$N={\int }_{\sigma (N)}\lambda 𝑑P(\lambda )$$

where $\sigma (N)$ denotes the spectrum of $N$ and $P$ is the projection valued measure associated with $N$.

Title	projections as noncommutative characteristic functions
Canonical name	ProjectionsAsNoncommutativeCharacteristicFunctions
Date of creation	2013-03-22 17:54:43
Last modified on	2013-03-22 17:54:43
Owner	asteroid (17536)
Last modified by	asteroid (17536)
Numerical id	11
Author	asteroid (17536)
Entry type	Feature
Classification	msc 46C07
Classification	msc 46L10
Classification	msc 46L51
Classification	msc 46C05