- Wiener–Khinchin theorem
The Wiener–Khinchin theorem (also known as the Wiener–Khintchine theorem and sometimes as the Wiener–Khinchin–Einstein theorem or the Khinchin–Kolmogorov theorem) states that the power
spectral density of a wide-sense-stationary random process is theFourier transform of the correspondingautocorrelation function. [cite book | title = Echo Signal Processing | author = Dennis Ward Ricker | publisher = Springer | year = 2003 | ibsn = 140207395X | url = http://books.google.com/books?id=NF2Tmty9nugC&pg=PA23&dq=%22power+spectral+density%22+%22energy+spectral+density%22&lr=&as_brr=3&ei=HZMvSPSWFZyStwPWsfyBAw&sig=1ZZcHwxXkErvNXtAHv21ijTXoP8#PPA23,M1 ] [cite book | title = Digital and Analog Communications Systems | author = Leon W. Couch II | edition = sixth ed. | publisher = Prentice Hall, New Jersey | year = 2001 | pages = 406-409] [cite book | title = Wireless Technologies: Circuits, Systems, and Devices | author = Krzysztof Iniewski | publisher = CRC Press | year = 2007 | isbn = 0849379962 | url = http://books.google.com/books?id=JJXrpazX9FkC&pg=PA390&dq=Wiener-Khinchin-Einstein&ei=1SxlSPGhB4jgsQPr5b3lDw&sig=ACfU3U2Phnk-zwJi57XrvNmdfosyg55FVA ]Continuous case::S_{xx}(f)=int_{-infty}^infty r_{xx}( au)e^{-j2pi f au} d auwhere
:r_{xx}( au) = operatorname{E}ig [, x(t)x^*(t- au) , ig]
is the autocorrelation function defined in terms of statistical expectation, and where
:S_{xx}(f)
is the power spectral density of the function x(t),. Note that the autocorrelation function is defined in terms of the expected value of a product, and that the Fourier transform of x(t), does not exist, in general, because stationary random functions are not square integrable.
The asterisk denotes complex conjugate, and can be omitted if the random process is real-valued.
Discrete case::S_{xx}(f)=sum_{k=-infty}^infty r_{xx} [k] e^{-j2pi k f}
where
:r_{xx} [k] = operatorname{E}ig [ , x [n] x^* [n-k] , ig]
and where
:S_{xx}(f)
is the power spectral density of the function with discrete values x [n] ,. Being a sampled and discrete-time sequence, the spectral density is periodic in the frequency domain.
Application
The theorem is useful for analyzing linear time-invariant systems, LTI systems, when the inputs and outputs are not square integrable, so their Fourier transforms do not exist. A corollary is that the Fourier transform of the autocorrelation function of the output of an LTI system is equal to the product of the Fourier transform of the autocorrelation function of the input of the system times the squared magnitude of the Fourier transform of the system impulse response. This works even when the Fourier transforms of the input and output signals do not exist because these signals are not square integrable, so the system inputs and outputs cannot be directly related by the Fourier transform of the impulse response.
Since the Fourier transform of the autocorrelation function of a signal is the power spectrum of the signal, this corollary is equivalent to saying that the power spectrum of the output is equal to the power spectrum of the input times the power
transfer function .This corollary is used in the parametric method of estimating for the power spectrum estimation.
Discrepancy of definition
By the definitions involving infinite integrals in the articles on
spectral density andautocorrelation , the Wiener–Khintchine theorem is a simple Fourier transform pair, trivially provable for any square integrable function, i.e. for functions whose Fourier transforms exist. More usefully, and historically, the theorem applies to wide-sense-stationary random processes, signals whose Fourier transforms do not exist, using the definition of autocorrelation function in terms of expected value rather than an infinite integral. This trivialization of the Wiener–Khintchine theorem is commonplace in modern technical literature, and obscures the contributions ofAleksandr Yakovlevich Khinchin ,Norbert Wiener , andAndrey Kolmogorov .References
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