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{{notability|date=February 2012}}
 
The '''autocorrelation technique''' is a method for estimating the dominating frequency in a [[Complex number|complex]] signal, as well as its variance. Specifically, it calculates the first two moments of the power spectrum, namely the mean and variance. It is also known as the '''pulse-pair algorithm''' in [[radar]] theory.
 
The algorithm is both computationally faster and significantly more accurate compared to the [[discrete Fourier transform|Fourier transform]], since the resolution is not limited by the number of samples used.
 
== Derivation ==
The [[autocorrelation]] of lag 1 can be expressed using the inverse Fourier transform of the power spectrum <math>S(\omega)</math>:
:<math> R(1) = \frac{1}{2\pi} \int_{-\pi}^{\pi} S(\omega) e^{i\,\omega\,1} d\omega. </math>
If we model the power spectrum as a single frequency <math>S(\omega) \ \stackrel{\mathrm{def}}{=}\ \delta(\omega - \omega_0)</math>, this becomes:
:<math> R(1) = \frac{1}{2\pi} \int_{-\pi}^{\pi} \delta(\omega - \omega_0) e^{i\,\omega} d\omega </math>
:<math> R(1) = \frac{1}{2\pi} e^{i\,\omega_0} </math>
where it is apparent that the phase of <math>R(1)</math> equals the signal frequency.
 
== Implementation ==
The mean frequency is calculated based on the [[autocorrelation]] with lag one, evaluated over a signal consisting of N samples:
:<math>\omega = \angle R_N(1) = \tan^{-1}\frac{im\{ R_N(1) \}}{re\{ R_N(1) \}}. </math>
The spectral variance is calculated as follows:
:<math>var\{ \omega \} = \frac{2}{N} \left( 1 - \frac{|R_N(1)|}{R_N(0)} \right). </math>
 
== Applications ==
* Estimation of blood velocity and turbulence in ''color flow imaging'' used in [[medical ultrasonography]].
* Estimation of target velocity in [[pulse-doppler radar]]
 
{{inline|date=February 2012}}
 
== External links ==
* [http://ieeexplore.ieee.org/xpl/abs_free.jsp?arNumber=1054886 A covariance approach to spectral moment estimation], Miller et al., IEEE Transactions on Information Theory. {{full|date=November 2012}}
* Doppler Radar Meteorological Observations [http://www.ofcm.gov/fmh11/fmh11partb/2005pdf/fmh-11B-2005.pdf Doppler Radar Theory].{{full|date=November 2012}} Autocorrelation technique described on p.2-11
* [http://server.oersted.dtu.dk/31655/documents/kasai_et_al_1985.pdf Real-Time Two-Dimensional Blood Flow Imaging Using an Autocorrelation Technique], by Chihiro Kasai, Koroku Namekawa, Akira Koyano, and Ryozo Omoto, IEEE Transactions on sonics and ultrasonics, May 1985 {{full|date=November 2012}}
 
[[Category:Radar theory]]
[[Category:Signal processing]]
[[Category:Time series analysis]]

Revision as of 12:52, 24 April 2013

Template:Notability

The autocorrelation technique is a method for estimating the dominating frequency in a complex signal, as well as its variance. Specifically, it calculates the first two moments of the power spectrum, namely the mean and variance. It is also known as the pulse-pair algorithm in radar theory.

The algorithm is both computationally faster and significantly more accurate compared to the Fourier transform, since the resolution is not limited by the number of samples used.

Derivation

The autocorrelation of lag 1 can be expressed using the inverse Fourier transform of the power spectrum S(ω):

R(1)=12πππS(ω)eiω1dω.

If we model the power spectrum as a single frequency S(ω)=defδ(ωω0), this becomes:

R(1)=12πππδ(ωω0)eiωdω
R(1)=12πeiω0

where it is apparent that the phase of R(1) equals the signal frequency.

Implementation

The mean frequency is calculated based on the autocorrelation with lag one, evaluated over a signal consisting of N samples:

ω=RN(1)=tan1im{RN(1)}re{RN(1)}.

The spectral variance is calculated as follows:

var{ω}=2N(1|RN(1)|RN(0)).

Applications

Template:Inline

External links