Complex random vector

In probability theory and statistics, a complex random vector is typically a tuple of complex-valued random variables, and generally is a random variable taking values in a vector space over the field of complex numbers. If ${\displaystyle Z_1,\dots ,Z_n}$ are complex-valued random variables, then the n-tuple ${\displaystyle (Z_1,\dots ,Z_n)}$ is a complex random vector. Complex random variables can always be considered as pairs of real random vectors: their real and imaginary parts.

Some concepts of real random vectors have a straightforward generalization to complex random vectors. For example, the definition of the mean of a complex random vector. Other concepts are unique to complex random vectors.

Applications of complex random vectors are found in digital signal processing.

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A complex random vector ${\displaystyle 𝐙=(Z_1,\dots ,Z_n{)}^T}$ on the probability space ${\displaystyle (\Omega ,ℱ,P)}$ is a function ${\displaystyle 𝐙:\Omega \to {ℂ}^n}$ such that the vector ${\displaystyle (\mathrm{\Re }(Z_1),\mathrm{\Im }(Z_1),\dots ,\mathrm{\Re }(Z_n),\mathrm{\Im }(Z_n){)}^T}$ is a real random vector on ${\displaystyle (\Omega ,ℱ,P)}$ where ${\displaystyle \mathrm{\Re }(z)}$ denotes the real part of ${\displaystyle z}$ and ${\displaystyle \mathrm{\Im }(z)}$ denotes the imaginary part of ${\displaystyle z}$.^[1]Template:Rp

The generalization of the cumulative distribution function from real to complex random variables is not obvious because expressions of the form ${\displaystyle P(Z\le 1+3i)}$ make no sense. However expressions of the form ${\displaystyle P(\mathrm{\Re }(Z)\le 1,\mathrm{\Im }(Z)\le 3)}$ make sense. Therefore, the cumulative distribution function ${\displaystyle F_{𝐙}:{ℂ}^n\mapsto [0,1]}$ of a random vector ${\displaystyle 𝐙=(Z_1,\mathrm{...},Z_n{)}^T}$ is defined as

where ${\displaystyle 𝐳=(z_1,\mathrm{...},z_n{)}^T}$.

As in the real case the expectation (also called expected value) of a complex random vector is taken component-wise.^[1]Template:Rp

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The covariance matrix (also called second central moment) ${\displaystyle {\mathrm{K}}_{𝐙𝐙}}$ contains the covariances between all pairs of components. The covariance matrix of an ${\displaystyle n\times 1}$ random vector is an ${\displaystyle n\times n}$ matrix whose ${\displaystyle (i,j)}$^th element is the covariance between the i ^th and the j ^th random variables.^[2]Template:Rp Unlike in the case of real random variables, the covariance between two random variables involves the complex conjugate of one of the two. Thus the covariance matrix is a Hermitian matrix.^[1]Template:Rp

${\displaystyle {\mathrm{K}}_{𝐙𝐙}=\left[\begin{array}{cccc}\mathrm{E}[(Z_1-\mathrm{E}[Z_1])\overline{(Z_1-\mathrm{E}[Z_1])}]& \mathrm{E}[(Z_1-\mathrm{E}[Z_1])\overline{(Z_2-\mathrm{E}[Z_2])}]& \cdots & \mathrm{E}[(Z_1-\mathrm{E}[Z_1])\overline{(Z_n-\mathrm{E}[Z_n])}]\\ \\ \mathrm{E}[(Z_2-\mathrm{E}[Z_2])\overline{(Z_1-\mathrm{E}[Z_1])}]& \mathrm{E}[(Z_2-\mathrm{E}[Z_2])\overline{(Z_2-\mathrm{E}[Z_2])}]& \cdots & \mathrm{E}[(Z_2-\mathrm{E}[Z_2])\overline{(Z_n-\mathrm{E}[Z_n])}]\\ \\ ⋮& ⋮& \ddots & ⋮\\ \\ \mathrm{E}[(Z_n-\mathrm{E}[Z_n])\overline{(Z_1-\mathrm{E}[Z_1])}]& \mathrm{E}[(Z_n-\mathrm{E}[Z_n])\overline{(Z_2-\mathrm{E}[Z_2])}]& \cdots & \mathrm{E}[(Z_n-\mathrm{E}[Z_n])\overline{(Z_n-\mathrm{E}[Z_n])}]\end{array}\right]}$

The pseudo-covariance matrix (also called relation matrix) is defined replacing Hermitian transposition by transposition in the definition above.

${\displaystyle {\mathrm{J}}_{𝐙𝐙}=\left[\begin{array}{cccc}\mathrm{E}[(Z_1-\mathrm{E}[Z_1])(Z_1-\mathrm{E}[Z_1])]& \mathrm{E}[(Z_1-\mathrm{E}[Z_1])(Z_2-\mathrm{E}[Z_2])]& \cdots & \mathrm{E}[(Z_1-\mathrm{E}[Z_1])(Z_n-\mathrm{E}[Z_n])]\\ \\ \mathrm{E}[(Z_2-\mathrm{E}[Z_2])(Z_1-\mathrm{E}[Z_1])]& \mathrm{E}[(Z_2-\mathrm{E}[Z_2])(Z_2-\mathrm{E}[Z_2])]& \cdots & \mathrm{E}[(Z_2-\mathrm{E}[Z_2])(Z_n-\mathrm{E}[Z_n])]\\ \\ ⋮& ⋮& \ddots & ⋮\\ \\ \mathrm{E}[(Z_n-\mathrm{E}[Z_n])(Z_1-\mathrm{E}[Z_1])]& \mathrm{E}[(Z_n-\mathrm{E}[Z_n])(Z_2-\mathrm{E}[Z_2])]& \cdots & \mathrm{E}[(Z_n-\mathrm{E}[Z_n])(Z_n-\mathrm{E}[Z_n])]\end{array}\right]}$

Properties

The covariance matrix is a hermitian matrix, i.e.^[1]Template:Rp

${\displaystyle {\mathrm{K}}_{𝐙𝐙}^H={\mathrm{K}}_{𝐙𝐙}}$.

The pseudo-covariance matrix is a symmetric matrix, i.e.

${\displaystyle {\mathrm{J}}_{𝐙𝐙}^T={\mathrm{J}}_{𝐙𝐙}}$.

The covariance matrix is a positive semidefinite matrix, i.e.

${\displaystyle {𝐚}^H{\mathrm{K}}_{𝐙𝐙}𝐚\ge 0\text{for all }𝐚\in {ℂ}^n}$.

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By decomposing the random vector ${\displaystyle 𝐙}$ into its real part ${\displaystyle 𝐗=\mathrm{\Re }(𝐙)}$ and imaginary part ${\displaystyle 𝐘=\mathrm{\Im }(𝐙)}$ (i.e. ${\displaystyle 𝐙=𝐗+i𝐘}$), the pair ${\displaystyle (𝐗,𝐘)}$ has a covariance matrix of the form:

${\displaystyle \left[\begin{array}{cc}{\mathrm{K}}_{𝐗𝐗}& {\mathrm{K}}_{𝐗𝐘}\\ {\mathrm{K}}_{𝐘𝐗}& {\mathrm{K}}_{𝐘𝐘}\end{array}\right]}$

The matrices ${\displaystyle {\mathrm{K}}_{𝐙𝐙}}$ and ${\displaystyle {\mathrm{J}}_{𝐙𝐙}}$ can be related to the covariance matrices of ${\displaystyle 𝐗}$ and ${\displaystyle 𝐘}$ via the following expressions:

${\displaystyle \begin{array}{cc}& {\mathrm{K}}_{𝐗𝐗}=\mathrm{E}[(𝐗-\mathrm{E}[𝐗])(𝐗-\mathrm{E}[𝐗]{)}^{\mathrm{T}}]=\frac{1}{2}\mathrm{Re}({\mathrm{K}}_{𝐙𝐙}+{\mathrm{J}}_{𝐙𝐙})\\ & {\mathrm{K}}_{𝐘𝐘}=\mathrm{E}[(𝐘-\mathrm{E}[𝐘])(𝐘-\mathrm{E}[𝐘]{)}^{\mathrm{T}}]=\frac{1}{2}\mathrm{Re}({\mathrm{K}}_{𝐙𝐙}-{\mathrm{J}}_{𝐙𝐙})\\ & {\mathrm{K}}_{𝐘𝐗}=\mathrm{E}[(𝐘-\mathrm{E}[𝐘])(𝐗-\mathrm{E}[𝐗]{)}^{\mathrm{T}}]=\frac{1}{2}\mathrm{Im}({\mathrm{J}}_{𝐙𝐙}+{\mathrm{K}}_{𝐙𝐙})\\ & {\mathrm{K}}_{𝐗𝐘}=\mathrm{E}[(𝐗-\mathrm{E}[𝐗])(𝐘-\mathrm{E}[𝐘]{)}^{\mathrm{T}}]=\frac{1}{2}\mathrm{Im}({\mathrm{J}}_{𝐙𝐙}-{\mathrm{K}}_{𝐙𝐙})\\ \end{array}}$

Conversely:

${\displaystyle \begin{array}{cc}& {\mathrm{K}}_{𝐙𝐙}={\mathrm{K}}_{𝐗𝐗}+{\mathrm{K}}_{𝐘𝐘}+i({\mathrm{K}}_{𝐘𝐗}-{\mathrm{K}}_{𝐗𝐘})\\ & {\mathrm{J}}_{𝐙𝐙}={\mathrm{K}}_{𝐗𝐗}-{\mathrm{K}}_{𝐘𝐘}+i({\mathrm{K}}_{𝐘𝐗}+{\mathrm{K}}_{𝐗𝐘})\end{array}}$

The cross-covariance matrix between two complex random vectors ${\displaystyle 𝐙,𝐖}$ is defined as:

${\displaystyle {\mathrm{K}}_{𝐙𝐖}=\left[\begin{array}{cccc}\mathrm{E}[(Z_1-\mathrm{E}[Z_1])\overline{(W_1-\mathrm{E}[W_1])}]& \mathrm{E}[(Z_1-\mathrm{E}[Z_1])\overline{(W_2-\mathrm{E}[W_2])}]& \cdots & \mathrm{E}[(Z_1-\mathrm{E}[Z_1])\overline{(W_n-\mathrm{E}[W_n])}]\\ \\ \mathrm{E}[(Z_2-\mathrm{E}[Z_2])\overline{(W_1-\mathrm{E}[W_1])}]& \mathrm{E}[(Z_2-\mathrm{E}[Z_2])\overline{(W_2-\mathrm{E}[W_2])}]& \cdots & \mathrm{E}[(Z_2-\mathrm{E}[Z_2])\overline{(W_n-\mathrm{E}[W_n])}]\\ \\ ⋮& ⋮& \ddots & ⋮\\ \\ \mathrm{E}[(Z_n-\mathrm{E}[Z_n])\overline{(W_1-\mathrm{E}[W_1])}]& \mathrm{E}[(Z_n-\mathrm{E}[Z_n])\overline{(W_2-\mathrm{E}[W_2])}]& \cdots & \mathrm{E}[(Z_n-\mathrm{E}[Z_n])\overline{(W_n-\mathrm{E}[W_n])}]\end{array}\right]}$

And the pseudo-cross-covariance matrix is defined as:

${\displaystyle {\mathrm{J}}_{𝐙𝐖}=\left[\begin{array}{cccc}\mathrm{E}[(Z_1-\mathrm{E}[Z_1])(W_1-\mathrm{E}[W_1])]& \mathrm{E}[(Z_1-\mathrm{E}[Z_1])(W_2-\mathrm{E}[W_2])]& \cdots & \mathrm{E}[(Z_1-\mathrm{E}[Z_1])(W_n-\mathrm{E}[W_n])]\\ \\ \mathrm{E}[(Z_2-\mathrm{E}[Z_2])(W_1-\mathrm{E}[W_1])]& \mathrm{E}[(Z_2-\mathrm{E}[Z_2])(W_2-\mathrm{E}[W_2])]& \cdots & \mathrm{E}[(Z_2-\mathrm{E}[Z_2])(W_n-\mathrm{E}[W_n])]\\ \\ ⋮& ⋮& \ddots & ⋮\\ \\ \mathrm{E}[(Z_n-\mathrm{E}[Z_n])(W_1-\mathrm{E}[W_1])]& \mathrm{E}[(Z_n-\mathrm{E}[Z_n])(W_2-\mathrm{E}[W_2])]& \cdots & \mathrm{E}[(Z_n-\mathrm{E}[Z_n])(W_n-\mathrm{E}[W_n])]\end{array}\right]}$

Two complex random vectors ${\displaystyle 𝐙}$ and ${\displaystyle 𝐖}$ are called uncorrelated if

${\displaystyle {\mathrm{K}}_{𝐙𝐖}={\mathrm{J}}_{𝐙𝐖}=0}$.

Template:Main Two complex random vectors ${\displaystyle 𝐙=(Z_1,\mathrm{...},Z_m{)}^T}$ and ${\displaystyle 𝐖=(W_1,\mathrm{...},W_n{)}^T}$ are called independent if

where ${\displaystyle F_{𝐙}(𝐳)}$ and ${\displaystyle F_{𝐖}(𝐰)}$ denote the cumulative distribution functions of ${\displaystyle 𝐙}$ and ${\displaystyle 𝐖}$ as defined in Template:EquationNote and ${\displaystyle F_{𝐙,𝐖}(𝐳,𝐰)}$ denotes their joint cumulative distribution function. Independence of ${\displaystyle 𝐙}$ and ${\displaystyle 𝐖}$ is often denoted by ${\displaystyle 𝐙\perp \perp 𝐖}$. Written component-wise, ${\displaystyle 𝐙}$ and ${\displaystyle 𝐖}$ are called independent if

${\displaystyle F_{Z_1,\dots ,Z_m,W_1,\dots ,W_n}(z_1,\dots ,z_m,w_1,\dots ,w_n)=F_{Z_1,\dots ,Z_m}(z_1,\dots ,z_m)\cdot F_{W_1,\dots ,W_n}(w_1,\dots ,w_n)\text{for all }{z}_1,\dots ,z_m,w_1,\dots ,w_n}$.

A complex random vector ${\displaystyle 𝐙}$ is called circularly symmetric if for every deterministic ${\displaystyle \phi \in [-\pi ,\pi )}$ the distribution of ${\displaystyle e^{\mathrm{i}\phi }𝐙}$ equals the distribution of ${\displaystyle 𝐙}$.^[3]Template:Rp

Properties

• The expectation of a circularly symmetric complex random vector is either zero or it is not defined.^[3]Template:Rp
• The pseudo-covariance matrix of a circularly symmetric complex random vector is zero.^[3]Template:Rp

A complex random vector ${\displaystyle 𝐙}$ is called proper if the following three conditions are all satisfied:^[1]Template:Rp

• ${\displaystyle \mathrm{E}[𝐙]=0}$ (zero mean)
• ${\displaystyle \mathrm{var}[Z_1]<\mathrm{\infty },\dots ,\mathrm{var}[Z_n]<\mathrm{\infty }}$ (all components have finite variance)
• ${\displaystyle \mathrm{E}[𝐙{𝐙}^T]=0}$

Two complex random vectors ${\displaystyle 𝐙,𝐖}$ are called jointly proper is the composite random vector ${\displaystyle (Z_1,Z_2,\dots ,Z_m,W_1,W_2,\dots ,W_n{)}^T}$ is proper.

Properties

• A complex random vector ${\displaystyle 𝐙}$ is proper if, and only if, for all (deterministic) vectors ${\displaystyle 𝐜\in {ℂ}^n}$ the complex random variable ${\displaystyle {𝐜}^T𝐙}$ is proper.^[1]Template:Rp
• Linear transformations of proper complex random vectors are proper, i.e. if ${\displaystyle 𝐙}$ is a proper random vectors with ${\displaystyle n}$ components and ${\displaystyle A}$ is a deterministic ${\displaystyle m\times n}$ matrix, then the complex random vector ${\displaystyle A𝐙}$ is also proper.^[1]Template:Rp
• Every circularly symmetric complex random vector with finite variance of all its components is proper.^[1]Template:Rp
• There are proper complex random vectors that are not circularly symmetric.^[1]Template:Rp
• A real random vector is proper if and only if it is constant.
• Two jointly proper complex random vectors are uncorrelated if and only if their covariance matrix is zero, i.e. if ${\displaystyle {\mathrm{K}}_{𝐙𝐖}=0}$.

The Cauchy-Schwarz inequality for complex random vectors is

${\displaystyle {|\mathrm{E}[{𝐙}^H𝐖]|}^2\le \mathrm{E}[{𝐙}^H𝐙]\mathrm{E}[|{𝐖}^H𝐖|]}$.

The characteristic function of a complex random vector ${\displaystyle 𝐙}$ with ${\displaystyle n}$ components is a function ${\displaystyle {ℂ}^n\to ℂ}$ defined by:^[1]Template:Rp

${\displaystyle {\phi }_{𝐙}(𝝎)=\mathrm{E}\left[e^{i\mathrm{\Re }({𝝎}^H𝐙)}\right]=\mathrm{E}\left[e^{i(\mathrm{\Re }({\omega }_1)\mathrm{\Re }(Z_1)+\mathrm{\Im }({\omega }_1)\mathrm{\Im }(Z_1)+\cdots +\mathrm{\Re }({\omega }_n)\mathrm{\Re }(Z_n)+\mathrm{\Im }({\omega }_n)\mathrm{\Im }(Z_n))}\right]}$

• Complex normal distribution
• Complex random variable (scalar case)

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