Autocovariance

Part of a series on Statistics
Correlation and covariance
File:CorrelationIcon.svg
For random vectors Autocorrelation matrix Cross-correlation matrix Auto-covariance matrix Cross-covariance matrix
For stochastic processes Autocorrelation function Cross-correlation function Autocovariance function Cross-covariance function
For deterministic signals Autocorrelation function Cross-correlation function Autocovariance function Cross-covariance function
v t e

In probability theory and statistics, given a stochastic process, the autocovariance is a function that gives the covariance of the process with itself at pairs of time points. Autocovariance is closely related to the autocorrelation of the process in question.

Auto-covariance of stochastic processes

Definition

With the usual notation ${\displaystyle \mathrm{E}}$ for the expectation operator, if the stochastic process ${\displaystyle \left\{X_t\right\}}$ has the mean function ${\displaystyle {\mu }_t=\mathrm{E}[X_t]}$, then the autocovariance is given by^{[1]: p. 162}

where ${\displaystyle t_1}$ and ${\displaystyle t_2}$ are two instances in time.

Definition for weakly stationary process

If ${\displaystyle \left\{X_t\right\}}$ is a weakly stationary (WSS) process, then the following are true:^{[1]: p. 163}

${\displaystyle {\mu }_{t_1}={\mu }_{t_2}\triangleq \mu }$ for all ${\displaystyle t_1,t_2}$

and

${\displaystyle \mathrm{E}[|X_t{|}^2]<\mathrm{\infty }}$ for all ${\displaystyle t}$

and

${\displaystyle {\mathrm{K}}_{XX}(t_1,t_2)={\mathrm{K}}_{XX}(t_2-t_1,0)\triangleq {\mathrm{K}}_{XX}(t_2-t_1)={\mathrm{K}}_{XX}(\tau ),}$

where ${\displaystyle \tau =t_2-t_1}$ is the lag time, or the amount of time by which the signal has been shifted. The autocovariance function of a WSS process is therefore given by:^{[2]: p. 517}

which is equivalent to

${\displaystyle {\mathrm{K}}_{XX}(\tau )=\mathrm{E}[(X_{t+\tau }-{\mu }_{t+\tau })(X_t-{\mu }_t)]=\mathrm{E}[X_{t+\tau }{X}_t]-{\mu }^2}$.

Normalization

It is common practice in some disciplines (e.g. statistics and time series analysis) to normalize the autocovariance function to get a time-dependent Pearson correlation coefficient. However in other disciplines (e.g. engineering) the normalization is usually dropped and the terms "autocorrelation" and "autocovariance" are used interchangeably. The definition of the normalized auto-correlation of a stochastic process is

${\displaystyle {\rho }_{XX}(t_1,t_2)=\frac{{\mathrm{K}}_{XX}(t_1,t_2)}{{\sigma }_{t_1}{\sigma }_{t_2}}=\frac{\mathrm{E}[(X_{t_1}-{\mu }_{t_1})(X_{t_2}-{\mu }_{t_2})]}{{\sigma }_{t_1}{\sigma }_{t_2}}}$.

If the function ${\displaystyle {\rho }_{XX}}$ is well-defined, its value must lie in the range ${\displaystyle [-1,1]}$, with 1 indicating perfect correlation and −1 indicating perfect anti-correlation. For a WSS process, the definition is

${\displaystyle {\rho }_{XX}(\tau )=\frac{{\mathrm{K}}_{XX}(\tau )}{{\sigma }^2}=\frac{\mathrm{E}[(X_t-\mu )(X_{t+\tau }-\mu )]}{{\sigma }^2}}$.

where

${\displaystyle {\mathrm{K}}_{XX}(0)={\sigma }^2}$.

Properties

Symmetry property

${\displaystyle {\mathrm{K}}_{XX}(t_1,t_2)=\overline{{\mathrm{K}}_{XX}(t_2,t_1)}}$^[3]: p.169

respectively for a WSS process:

${\displaystyle {\mathrm{K}}_{XX}(\tau )=\overline{{\mathrm{K}}_{XX}(-\tau )}}$^[3]: p.173

Linear filtering

The autocovariance of a linearly filtered process ${\displaystyle \left\{Y_t\right\}}$

${\displaystyle Y_t={\displaystyle \sum _{k=-\mathrm{\infty }}^{\mathrm{\infty }}}{a}_k{X}_{t+k}}$

is

${\displaystyle K_{YY}(\tau )={\displaystyle \sum _{k,l=-\mathrm{\infty }}^{\mathrm{\infty }}}{a}_k{a}_l{K}_{XX}(\tau +k-l).}$

Calculating turbulent diffusivity

Autocovariance can be used to calculate turbulent diffusivity.^[4] Turbulence in a flow can cause the fluctuation of velocity in space and time. Thus, we are able to identify turbulence through the statistics of those fluctuations^{[citation needed]}. Reynolds decomposition is used to define the velocity fluctuations ${\displaystyle u^{\prime }(x,t)}$ (assume we are now working with 1D problem and ${\displaystyle U(x,t)}$ is the velocity along ${\displaystyle x}$ direction):

${\displaystyle U(x,t)=⟨U(x,t)⟩+u^{\prime }(x,t),}$

where ${\displaystyle U(x,t)}$ is the true velocity, and ${\displaystyle ⟨U(x,t)⟩}$ is the expected value of velocity. If we choose a correct ${\displaystyle ⟨U(x,t)⟩}$, all of the stochastic components of the turbulent velocity will be included in ${\displaystyle u^{\prime }(x,t)}$. To determine ${\displaystyle ⟨U(x,t)⟩}$, a set of velocity measurements that are assembled from points in space, moments in time or repeated experiments is required. If we assume the turbulent flux ${\displaystyle ⟨u^{\prime }{c}^{\prime }⟩}$ (${\displaystyle c^{\prime }=c-⟨c⟩}$, and c is the concentration term) can be caused by a random walk, we can use Fick's laws of diffusion to express the turbulent flux term:

${\displaystyle J_{{\text{turbulence}}_x}=⟨u^{\prime }{c}^{\prime }⟩\approx D_{T_x}\frac{\partial ⟨c⟩}{\partial x}.}$

The velocity autocovariance is defined as

${\displaystyle K_{XX}\equiv ⟨u^{\prime }(t_0)u^{\prime }(t_0+\tau )⟩}$ or ${\displaystyle K_{XX}\equiv ⟨u^{\prime }(x_0)u^{\prime }(x_0+r)⟩,}$

where ${\displaystyle \tau }$ is the lag time, and ${\displaystyle r}$ is the lag distance. The turbulent diffusivity ${\displaystyle D_{T_x}}$ can be calculated using the following 3 methods:

Auto-covariance of random vectors

See also

• Autoregressive process
• Correlation
• Cross-covariance
• Cross-correlation
• Noise covariance estimation (as an application example)

References

Further reading

• Hoel, P. G. (1984). Mathematical Statistics (Fifth ed.). New York: Wiley. ISBN 978-0-471-89045-4.
• Lecture notes on autocovariance from WHOI