Positive element

In mathematics, an element of a *-algebra is called positive if it is the sum of elements of the form ${\displaystyle a^{*}a}$.^[1]

Definition

Let ${\displaystyle {𝒜}}$ be a *-algebra. An element ${\displaystyle a\in {𝒜}}$ is called positive if there are finitely many elements ${\displaystyle a_k\in {𝒜}(k=1,2,\dots ,n)}$, so that $a={\sum }_{k=1}^n{a}_k^{*}{a}_k$ holds.^[1] This is also denoted by ${\displaystyle a\ge 0}$.^[2] The set of positive elements is denoted by ${\displaystyle {{𝒜}}_{+}}$. A special case from particular importance is the case where ${\displaystyle {𝒜}}$ is a complete normed *-algebra, that satisfies the C*-identity ($$\begin{gathered} {\displaystyle \Vert a^{*}a\Vert ={\Vert a\Vert }^2 \\ \mathrm{\forall }a\in {𝒜}} \end{gathered}$$), which is called a C*-algebra.

Examples

• The unit element ${\displaystyle e}$ of an unital *-algebra is positive.
• For each element ${\displaystyle a\in {𝒜}}$, the elements ${\displaystyle a^{*}a}$ and ${\displaystyle a{a}^{*}}$ are positive by definition.^[1]

In case ${\displaystyle {𝒜}}$ is a C*-algebra, the following holds:

• Let ${\displaystyle a\in {{𝒜}}_N}$ be a normal element, then for every positive function ${\displaystyle f\ge 0}$ which is continuous on the spectrum of ${\displaystyle a}$ the continuous functional calculus defines a positive element ${\displaystyle f(a)}$.^[3]
• Every projection, i.e. every element ${\displaystyle a\in {𝒜}}$ for which ${\displaystyle a=a^{*}=a^2}$ holds, is positive. For the spectrum ${\displaystyle \sigma (a)}$ of such an idempotent element, ${\displaystyle \sigma (a)\subseteq \{0,1\}}$ holds, as can be seen from the continuous functional calculus.^[3]

Criteria

Let ${\displaystyle {𝒜}}$ be a C*-algebra and ${\displaystyle a\in {𝒜}}$. Then the following are equivalent:^[4]

• For the spectrum ${\displaystyle \sigma (a)\subseteq [0,\mathrm{\infty })}$ holds and ${\displaystyle a}$ is a normal element.
• There exists an element ${\displaystyle b\in {𝒜}}$, such that ${\displaystyle a=b{b}^{*}}$.
• There exists a (unique) self-adjoint element ${\displaystyle c\in {{𝒜}}_{sa}}$ such that ${\displaystyle a=c^2}$.

If ${\displaystyle {𝒜}}$ is a unital *-algebra with unit element ${\displaystyle e}$, then in addition the following statements are equivalent:^[5]

• ${\displaystyle \Vert te-a\Vert \le t}$ for every ${\displaystyle t\ge \Vert a\Vert }$ and ${\displaystyle a}$ is a self-adjoint element.
• ${\displaystyle \Vert te-a\Vert \le t}$ for some ${\displaystyle t\ge \Vert a\Vert }$ and ${\displaystyle a}$ is a self-adjoint element.

Properties

In *-algebras

Let ${\displaystyle {𝒜}}$ be a *-algebra. Then:

• If ${\displaystyle a\in {{𝒜}}_{+}}$ is a positive element, then ${\displaystyle a}$ is self-adjoint.^[6]
• The set of positive elements ${\displaystyle {{𝒜}}_{+}}$ is a convex cone in the real vector space of the self-adjoint elements ${\displaystyle {{𝒜}}_{sa}}$. This means that ${\displaystyle \alpha a,a+b\in {{𝒜}}_{+}}$ holds for all ${\displaystyle a,b\in {𝒜}}$ and ${\displaystyle \alpha \in [0,\mathrm{\infty })}$.^[6]
• If ${\displaystyle a\in {{𝒜}}_{+}}$ is a positive element, then ${\displaystyle b^{*}ab}$ is also positive for every element ${\displaystyle b\in {𝒜}}$.^[7]
• For the linear span of ${\displaystyle {{𝒜}}_{+}}$ the following holds: ${\displaystyle ⟨{{𝒜}}_{+}⟩={{𝒜}}^2}$ and ${\displaystyle {{𝒜}}_{+}-{{𝒜}}_{+}={{𝒜}}_{sa}\cap {{𝒜}}^2}$.^[8]

In C*-algebras

Let ${\displaystyle {𝒜}}$ be a C*-algebra. Then:

• Using the continuous functional calculus, for every ${\displaystyle a\in {{𝒜}}_{+}}$ and ${\displaystyle n\in \mathbb{\mathbb{N}}}$ there is a uniquely determined ${\displaystyle b\in {{𝒜}}_{+}}$ that satisfies ${\displaystyle b^n=a}$, i.e. a unique ${\displaystyle n}$-th root. In particular, a square root exists for every positive element. Since for every ${\displaystyle b\in {𝒜}}$ the element ${\displaystyle b^{*}b}$ is positive, this allows the definition of a unique absolute value: $|b|=(b^{*}b{)}^{\frac{1}{2}}$.^[9]
• For every real number ${\displaystyle \alpha \ge 0}$ there is a positive element ${\displaystyle a^{\alpha }\in {{𝒜}}_{+}}$ for which ${\displaystyle a^{\alpha }{a}^{\beta }=a^{\alpha +\beta }}$ holds for all ${\displaystyle \beta \in [0,\mathrm{\infty })}$. The mapping ${\displaystyle \alpha \mapsto a^{\alpha }}$ is continuous. Negative values for ${\displaystyle \alpha }$ are also possible for invertible elements ${\displaystyle a}$.^[7]
• Products of commutative positive elements are also positive. So if ${\displaystyle ab=ba}$ holds for positive ${\displaystyle a,b\in {{𝒜}}_{+}}$, then ${\displaystyle ab\in {{𝒜}}_{+}}$.^[5]
• Each element ${\displaystyle a\in {𝒜}}$ can be uniquely represented as a linear combination of four positive elements. To do this, ${\displaystyle a}$ is first decomposed into the self-adjoint real and imaginary parts and these are then decomposed into positive and negative parts using the continuous functional calculus.^[10] For it holds that ${\displaystyle {{𝒜}}_{sa}={{𝒜}}_{+}-{{𝒜}}_{+}}$, since ${\displaystyle {{𝒜}}^2={𝒜}}$.^[8]
• If both ${\displaystyle a}$ and ${\displaystyle -a}$ are positive ${\displaystyle a=0}$ holds.^[5]
• If ${\displaystyle {ℬ}}$ is a C*-subalgebra of ${\displaystyle {𝒜}}$, then ${\displaystyle {{ℬ}}_{+}={ℬ}\cap {{𝒜}}_{+}}$.^[5]
• If ${\displaystyle {ℬ}}$ is another C*-algebra and ${\displaystyle \mathrm{\Phi }}$ is a *-homomorphism from ${\displaystyle {𝒜}}$ to ${\displaystyle {ℬ}}$, then ${\displaystyle \mathrm{\Phi }({{𝒜}}_{+})=\mathrm{\Phi }({𝒜})\cap {{ℬ}}_{+}}$ holds.^[11]
• If ${\displaystyle a,b\in {{𝒜}}_{+}}$ are positive elements for which ${\displaystyle ab=0}$, they commutate and ${\displaystyle \Vert a+b\Vert =\max (\Vert a\Vert ,\Vert b\Vert )}$ holds. Such elements are called orthogonal and one writes ${\displaystyle a\mathrm{\perp }b}$.^[12]

Partial order

Let ${\displaystyle {𝒜}}$ be a *-algebra. The property of being a positive element defines a translation invariant partial order on the set of self-adjoint elements ${\displaystyle {{𝒜}}_{sa}}$. If ${\displaystyle b-a\in {{𝒜}}_{+}}$ holds for ${\displaystyle a,b\in {𝒜}}$, one writes ${\displaystyle a\le b}$ or ${\displaystyle b\ge a}$.^[13] This partial order fulfills the properties ${\displaystyle ta\le tb}$ and ${\displaystyle a+c\le b+c}$ for all ${\displaystyle a,b,c\in {{𝒜}}_{sa}}$ with ${\displaystyle a\le b}$ and ${\displaystyle t\in [0,\mathrm{\infty })}$.^[8] If ${\displaystyle {𝒜}}$ is a C*-algebra, the partial order also has the following properties for ${\displaystyle a,b\in {𝒜}}$:

• If ${\displaystyle a\le b}$ holds, then ${\displaystyle c^{*}ac\le c^{*}bc}$ is true for every ${\displaystyle c\in {𝒜}}$. For every ${\displaystyle c\in {{𝒜}}_{+}}$ that commutates with ${\displaystyle a}$ and ${\displaystyle b}$ even ${\displaystyle ac\le bc}$ holds.^[14]
• If ${\displaystyle -b\le a\le b}$ holds, then ${\displaystyle \Vert a\Vert \le \Vert b\Vert }$.^[15]
• If ${\displaystyle 0\le a\le b}$ holds, then $a^{\alpha }\le b^{\alpha }$ holds for all real numbers ${\displaystyle 0<\alpha \le 1}$.^[16]
• If ${\displaystyle a}$ is invertible and ${\displaystyle 0\le a\le b}$ holds, then ${\displaystyle b}$ is invertible and for the inverses ${\displaystyle b^{-1}\le a^{-1}}$ holds.^[15]

See also

• Nonnegative matrix
• Positive operator (Hilbert space)

Citations

References

Bibliography