Journal ArticleDOI
The fractional Fourier transform and time-frequency representations
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TLDR
The authors briefly introduce the functional Fourier transform and a number of its properties and present some new results: the interpretation as a rotation in the time-frequency plane, and the FRFT's relationships with time- frequencies such as the Wigner distribution, the ambiguity function, the short-time Fouriertransform and the spectrogram.Abstract:
The functional Fourier transform (FRFT), which is a generalization of the classical Fourier transform, was introduced a number of years ago in the mathematics literature but appears to have remained largely unknown to the signal processing community, to which it may, however, be potentially useful. The FRFT depends on a parameter /spl alpha/ and can be interpreted as a rotation by an angle /spl alpha/ in the time-frequency plane. An FRFT with /spl alpha/=/spl pi//2 corresponds to the classical Fourier transform, and an FRFT with /spl alpha/=0 corresponds to the identity operator. On the other hand, the angles of successively performed FRFTs simply add up, as do the angles of successive rotations. The FRFT of a signal can also be interpreted as a decomposition of the signal in terms of chirps. The authors briefly introduce the FRFT and a number of its properties and then present some new results: the interpretation as a rotation in the time-frequency plane, and the FRFT's relationships with time-frequency representations such as the Wigner distribution, the ambiguity function, the short-time Fourier transform and the spectrogram. These relationships have a very simple and natural form and support the FRFT's interpretation as a rotation operator. Examples of FRFTs of some simple signals are given. An example of the application of the FRFT is also given. >read more
Citations
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Proceedings ArticleDOI
Joint fractional representations
TL;DR: In this article, the authors derived the formulation of joint fractional representations (JFRs) by using Cohen's (1995) characteristic function operator method, which generalizes conventional time-frequency representations into fractional domains which are defined by the fractional Fourier transform.
Proceedings ArticleDOI
Chirp signal analysis based on PWD in fractional Fourier transform domain
Li Jing,Wang Shuxun,Wang Fei +2 more
TL;DR: In this paper, a pseudo Wigner distribution in the fractional Fourier transform (FT) domain is proposed to analyze single or multi-component chirp signals, which preserves the WD auto-terms and cancels the cross-terms when there are several signal components.
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A New Singular Spectrum Decomposition Method Based on Cao Algorithm and Amplitude Aware Permutation Entropy
Hong Yang,Aohan Zhang,Guohui Li +2 more
TL;DR: The simulation results show that ISSD has the ability to identify noise and can effectively avoid over-decomposition, and can accurately extract the DC contained in the original signal to avoid energy loss.
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Special affine wavelet transform and the corresponding Poisson summation formula
TL;DR: This work proposes a highly flexible time-frequency transform namely, the special affine wavelet transform (SAWT) and investigates the associated constant $Q$-property in the joint time- frequency domain and derives an analogue of the Poisson summation formula for the proposed special affines wavelets transform.
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Estimation of FM signal parameters in impulse noise environments
TL;DR: A modification of the discrete chirp Fourier transform, called the robust DCFT, produces highly accurate results in impulse noise environments, while for the Gaussian noise it is only slightly worse than the standard one.
References
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Image rotation, Wigner rotation, and the fractional Fourier transform
TL;DR: In this article, the degree p = 1 is assigned to the ordinary Fourier transform and the degree P = 1/2 to the fractional transform, where p is the degree of the optical fiber.
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Time-frequency representation of digital signals and systems based on short-time Fourier analysis
TL;DR: In this article, the authors developed a representation for discrete-time signals and systems based on short-time Fourier analysis and showed that a class of linear-filtering problems can be represented as the product of the time-varying frequency response of the filter multiplied by the short time Fourier transform of the input signal.