Power spectrum: Difference between revisions
From Glossary of Meteorology
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#<div class="definition"><div class="short_definition">The square of the [[amplitude]] of the (complex) Fourier coefficient of a given periodic function.</div><br/> <div class="paragraph">Thus if ''f''(''t'') is periodic with [[period]] ''T'', its [[Fourier coefficients]] are <div class="display-formula"><blockquote>[[File:ams2001glos-Pe48.gif|link=|center|ams2001glos-Pe48]]</blockquote></div> where ω = 2π/''T'', and the power spectrum of ''f''(''t'') is <div class="inline-formula">[[File:ams2001glos-Pex06.gif|link=|ams2001glos-Pex06]]</div>. Here ''n'' takes integral values and the [[spectrum]] is discrete. The total [[energy]] of the periodic function is infinite, but the [[power]], or energy per unit period, is finite. In the case of the [[aperiodic]] function containing finite total energy, the [[energy density spectrum]] is the corresponding [[spectral function]]. This is a continuous function of [[frequency]] and therefore has [[dimensions]] of energy/frequency (energy density). In the case of a [[random]] function containing infinite total energy but not periodic, the [[power density spectrum]] is the corresponding spectral function. The mathematical conditions governing analogous theorems in these three classes of functions are different. However, when actual computations of observational data are involved, a finite number of discrete values are used, and the effect is the same as if the function were assumed to be periodic outside the interval of computation. Thus, it is the power spectrum that is exhibited. But all types of spectra referred to may be considered as measures of the contribution of given frequencies in the Fourier representation of the original function. The terms | #<div class="definition"><div class="short_definition">The square of the [[amplitude]] of the (complex) Fourier coefficient of a given periodic function.</div><br/> <div class="paragraph">Thus if ''f''(''t'') is periodic with [[period]] ''T'', its [[Fourier coefficients]] are <div class="display-formula"><blockquote>[[File:ams2001glos-Pe48.gif|link=|center|ams2001glos-Pe48]]</blockquote></div> where ω = 2π/''T'', and the power spectrum of ''f''(''t'') is <div class="inline-formula">[[File:ams2001glos-Pex06.gif|link=|ams2001glos-Pex06]]</div>. Here ''n'' takes integral values and the [[spectrum]] is discrete. The total [[energy]] of the periodic function is infinite, but the [[power]], or energy per unit period, is finite. In the case of the [[aperiodic]] function containing finite total energy, the [[energy density spectrum]] is the corresponding [[spectral function]]. This is a continuous function of [[frequency]] and therefore has [[dimensions]] of energy/frequency (energy density). In the case of a [[random]] function containing infinite total energy but not periodic, the [[power density spectrum]] is the corresponding spectral function. The mathematical conditions governing analogous theorems in these three classes of functions are different. However, when actual computations of observational data are involved, a finite number of discrete values are used, and the effect is the same as if the function were assumed to be periodic outside the interval of computation. Thus, it is the power spectrum that is exhibited. But all types of spectra referred to may be considered as measures of the contribution of given frequencies in the Fourier representation of the original function. The terms "power" and "energy" are usually retained to indicate relative dimensions regardless of the actual dimensions of the functions analyzed, which may be functions of space as well as time. Computation of the power spectrum in practice may be facilitated by use of the theorem that it is the Fourier coefficient of the [[autocorrelation function]].</div><br/> </div> | ||
#<div class="definition"><div class="short_definition"><br/>''Same as'' [[power density spectrum]].</div><br/> </div> | #<div class="definition"><div class="short_definition"><br/>''Same as'' [[power density spectrum]].</div><br/> </div> | ||
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Latest revision as of 15:53, 20 February 2012
power spectrum
- The square of the amplitude of the (complex) Fourier coefficient of a given periodic function.
Thus if f(t) is periodic with period T, its Fourier coefficients arewhere ω = 2π/T, and the power spectrum of f(t) is . Here n takes integral values and the spectrum is discrete. The total energy of the periodic function is infinite, but the power, or energy per unit period, is finite. In the case of the aperiodic function containing finite total energy, the energy density spectrum is the corresponding spectral function. This is a continuous function of frequency and therefore has dimensions of energy/frequency (energy density). In the case of a random function containing infinite total energy but not periodic, the power density spectrum is the corresponding spectral function. The mathematical conditions governing analogous theorems in these three classes of functions are different. However, when actual computations of observational data are involved, a finite number of discrete values are used, and the effect is the same as if the function were assumed to be periodic outside the interval of computation. Thus, it is the power spectrum that is exhibited. But all types of spectra referred to may be considered as measures of the contribution of given frequencies in the Fourier representation of the original function. The terms "power" and "energy" are usually retained to indicate relative dimensions regardless of the actual dimensions of the functions analyzed, which may be functions of space as well as time. Computation of the power spectrum in practice may be facilitated by use of the theorem that it is the Fourier coefficient of the autocorrelation function.
Same as power density spectrum.