q-Gaussian process

q-Gaussian processes are deformations of the usual Gaussian distribution. There are several different versions of this; here we treat a multivariate deformation, also addressed as q-Gaussian process, arising from free probability theory and corresponding to deformations of the canonical commutation relations. For other deformations of Gaussian distributions, see q-Gaussian distribution and Gaussian q-distribution.

The q-Gaussian process was formally introduced in a paper by Frisch and Bourret^[1] under the name of parastochastics, and also later by Greenberg^[2] as an example of infinite statistics. It was mathematically established and investigated in papers by Bozejko and Speicher^[3] and by Bozejko, Kümmerer, and Speicher^[4] in the context of non-commutative probability.

It is given as the distribution of sums of creation and annihilation operators in a q-deformed Fock space. The calculation of moments of those operators is given by a q-deformed version of a Wick formula or Isserlis formula. The specification of a special covariance in the underlying Hilbert space leads to the q-Brownian motion,^[4] a special non-commutative version of classical Brownian motion.

In the following ${\displaystyle q\in [-1,1]}$ is fixed. Consider a Hilbert space ${\displaystyle {\mathscr{H}}}$. On the algebraic full Fock space

${\displaystyle {{ℱ}}_{\text{alg}}({\mathscr{H}})=\underset{n\ge 0}{⨁}{{\mathscr{H}}}^{\otimes n},}$

where ${\displaystyle {{\mathscr{H}}}^0=\mathbb{ℂ}\mathrm{\Omega }}$ with a norm one vector ${\displaystyle \mathrm{\Omega }}$, called vacuum, we define a q-deformed inner product as follows:

${\displaystyle ⟨h_1\otimes \cdots \otimes h_n,g_1\otimes \cdots \otimes g_m{⟩}_q={\delta }_{nm}\sum _{\sigma \in S_n}{\displaystyle \prod _{r=1}^n}⟨h_r,g_{\sigma (r)}⟩q^{i(\sigma )},}$

where ${\displaystyle i(\sigma )=\mathrm{\#}\{(k,\ell )\mid 1\le k<\ell \le n;\sigma (k)>\sigma (\ell )\}}$ is the number of inversions of ${\displaystyle \sigma \in S_n}$.

The q-Fock space^[5] is then defined as the completion of the algebraic full Fock space with respect to this inner product

${\displaystyle {{ℱ}}_q({\mathscr{H}})=\stackrel{⟨\cdot ,\cdot {⟩}_q}{\stackrel{‾}{\underset{n\ge 0}{⨁}{{\mathscr{H}}}^{\otimes n}}}.}$

For ${\displaystyle -1<q<1}$ the q-inner product is strictly positive.^[3][6] For ${\displaystyle q=1}$ and ${\displaystyle q=-1}$ it is positive, but has a kernel, which leads in these cases to the symmetric and anti-symmetric Fock spaces, respectively.

For ${\displaystyle h\in {\mathscr{H}}}$ we define the q-creation operator ${\displaystyle a^{*}(h)}$, given by

${\displaystyle a^{*}(h)\mathrm{\Omega }=h,a^{*}(h)h_1\otimes \cdots \otimes h_n=h\otimes h_1\otimes \cdots \otimes h_n.}$

Its adjoint (with respect to the q-inner product), the q-annihilation operator ${\displaystyle a(h)}$, is given by

${\displaystyle a(h)\mathrm{\Omega }=0,a(h)h_1\otimes \cdots \otimes h_n={\displaystyle \sum _{r=1}^n}{q}^{r-1}⟨h,h_r⟩h_1\otimes \cdots \otimes h_{r-1}\otimes h_{r+1}\otimes \cdots \otimes h_n.}$

Those operators satisfy the q-commutation relations^[7]

${\displaystyle a(f)a^{*}(g)-q{a}^{*}(g)a(f)=⟨f,g⟩\cdot 1(f,g\in {\mathscr{H}}).}$

For ${\displaystyle q=1}$, ${\displaystyle q=0}$, and ${\displaystyle q=-1}$ this reduces to the CCR-relations, the Cuntz relations, and the CAR-relations, respectively. With the exception of the case ${\displaystyle q=1,}$ the operators ${\displaystyle a^{*}(f)}$ are bounded.

Operators of the form ${\displaystyle s_q(h)=a(h)+a^{*}(h)}$ for ${\displaystyle h\in {\mathscr{H}}}$ are called q-Gaussian^[5] (or q-semicircular^[8]) elements.

On ${\displaystyle {{ℱ}}_q({\mathscr{H}})}$ we consider the vacuum expectation state ${\displaystyle \tau (T)=⟨\mathrm{\Omega },T\mathrm{\Omega }⟩}$, for ${\displaystyle T\in {ℬ}({ℱ}({\mathscr{H}}))}$.

The (multivariate) q-Gaussian distribution or q-Gaussian process^[4][9] is defined as the non commutative distribution of a collection of q-Gaussians with respect to the vacuum expectation state. For ${\displaystyle h_1,\dots ,h_p\in {\mathscr{H}}}$ the joint distribution of ${\displaystyle s_q(h_1),\dots ,s_q(h_p)}$ with respect to ${\displaystyle \tau }$ can be described in the following way,:^[1][3] for any ${\displaystyle i\{1,\dots ,k\}\to \{1,\dots ,p\}}$ we have

${\displaystyle \tau (s_q(h_{i(1)})\cdots s_q(h_{i(k)}))=\sum _{\pi \in {{𝒫}}_2(k)}{q}^{cr(\pi )}\prod _{(r,s)\in \pi }⟨h_{i(r)},h_{i(s)}⟩,}$

where ${\displaystyle cr(\pi )}$ denotes the number of crossings of the pair-partition ${\displaystyle \pi }$. This is a q-deformed version of the Wick/Isserlis formula.

For p = 1, the q-Gaussian distribution is a probability measure on the interval ${\displaystyle [-2/\sqrt{1-q},2/\sqrt{1-q}]}$, with analytic formulas for its density.^[10] For the special cases ${\displaystyle q=1}$, ${\displaystyle q=0}$, and ${\displaystyle q=-1}$, this reduces to the classical Gaussian distribution, the Wigner semicircle distribution, and the symmetric Bernoulli distribution on ${\displaystyle \pm 1}$. The determination of the density follows from old results^[11] on corresponding orthogonal polynomials.

The von Neumann algebra generated by ${\displaystyle s_q(h_i)}$, for ${\displaystyle h_i}$ running through an orthonormal system ${\displaystyle (h_i{)}_{i\in I}}$ of vectors in ${\displaystyle {\mathscr{H}}}$, reduces for ${\displaystyle q=0}$ to the famous free group factors ${\displaystyle L(F_{|I|})}$. Understanding the structure of those von Neumann algebras for general q has been a source of many investigations.^[12] It is now known, by work of Guionnet and Shlyakhtenko,^[13] that at least for finite I and for small values of q, the von Neumann algebra is isomorphic to the corresponding free group factor.

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