Revision as of 18:44, 4 November 2010 edit EJ257T40R (talk \| contribs) 14 edits Sentence structure and added to the limitations of the STFT ← Previous edit		Revision as of 03:36, 20 February 2011 edit undo 174.3.227.184 (talk) →Introduction Next edit →
Line 5: ==Introduction== In the field of [[time-frequency analysis]], the goal is to define signal formulations that are used for representing the signal in a joint time-frequency ___domain (see also [[time-frequency representation]]s<ref>B. Boashash, “Time-Frequency Concepts”, Chapter 1, pp. 3–28, in B. Boashash, ed,, Time-Frequency Signal Analysis & Processing: A Comprehensive Reference, Elsevier Science, Oxford, 2003; ISBN 008044335.</ref>). There are several methods and transforms called "time-frequency distributions" (TFDs).<ref>B. Boashash, “Heuristic Formulation of Time-Frequency Distributions”, Chapter 2, pp. 29–58, in B. Boashash, editor, Time-Frequency Signal Analysis and Processing: A Comprehensive Reference, Elsevier Science, Oxford, 2003; ISBN 008044335.</ref> The most useful and used methods form a class referred to as "quadratic" or [[bilinear time-frequency distribution]]s. A core member of this class is the [[Wigner-Ville distribution]] (WVD),<ref>B. Boashash, "Note on the Use of the Wigner Distribution for Time Frequency Signal Analysis", IEEE Transactions on Acoustics, Speech, and Signal Processing, Vol. 36, No. 9, pp. 1518–1521, Sept. 1988</ref> as all other TFDs can be written as a smoothed version of the WVD. Another popular member of this class is the [[spectrogram]] which is the square of the magnitude of the [[short-time Fourier transform]] (STFT). The spectrogram has the advantage of being positive and is easy to interpret, but has disadvantages like being irreversible which means that once the spectrogram of a signal is computed, the original signal can't be extracted from the spectrogram. The theory and methodology for defining a TFD that verifies certain desirable properties is given in the "Theory of Quadratic TFDs" <ref>B. Boashash, “Theory of Quadratic TFDs”, Chapter 3, pp. 59–82, in B. Boashash, editor, Time-Frequency Signal Analysis & Processing: A Comprehensive Reference, Elsevier, Oxford, 2003; ISBN 0080443354.</ref>. The scope of this article is to outline some elements of the procedure to transform one distribution into another. The method used to transform a ~~distirbution~~distribution is borrowed from [[quantum mechanics]], even though the subject matter of the article is "signal processing". Noting that a signal can recovered from a particular distribution under certain conditions, given a certain TFD ρ1(t,f) representing the signal in a joint time-frequency ___domain, another different TFD ρ2(t,f) of the same signal can be obtained to calculate any other distribution, by simple smoothing or filtering; some of these relationships are shown below. A full treatment of the question can be given from a signal processing perspective.<ref>B. Boashash, editor, “Time-Frequency Signal Analysis and Processing – A Comprehensive Reference”, Elsevier Science, Oxford, 2003; ISBN 0080443354</ref>. ==General class==

Transformation between distributions in time–frequency analysis: Difference between revisions