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
Detection of moving target based on fractional Fourier transform in SAR clutter
TL;DR: Simulation analysis indicates that the time-delay balance method based on FRFT shows its advantages in a background with strong clutter.
Journal ArticleDOI
Fractional Fourier transform based underwater multi-targets direction-of-arrival estimation using wideband linear chirps
TL;DR: The revised RCB (RRCB) algorithm is proposed to solve the DOA estimation problem with a small number of snapshots and results show that FRFT based array signal processing method can achieve much narrower main lobe and higher main-to-side lobe ratio in low signal-to–noise ratio conditions.
Proceedings ArticleDOI
The Generalized Weighted Fractional Fourier Transform and its Application to Image Encryption
TL;DR: In this paper, a generalized weighted fractional Fourier transform (GWFRFT) was proposed for digital image encryption, which is a generalization of Shih's FRFT with two additional 4D vector parameters.
Book ChapterDOI
Parameter Estimation of LFM Signal by Direct and Spline Interpolation Based on FrFT
Jun Song,Yunfei Liu +1 more
TL;DR: In this article, a direct and spline interpolation method, along with a coarse search, is investigated and used for parameter estimation of linear frequency modulation (LFM) signal based on Fractional Fourier Transform (FrFT).
Journal ArticleDOI
An Efficient VLSI Architecture for Computation of Discrete Fractional Fourier Transform
TL;DR: An efficient CORDIC-based architecture for computing discrete fractional Fourier transform (DFrFT) is proposed which brings down the computational complexity and hardware requirements and provides the flexibility to change the user defined fractional angles to compute DFrFT on-the-fly.
References
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The Fractional Order Fourier Transform and its Application to Quantum Mechanics
TL;DR: In this article, a generalized operational calculus is developed, paralleling the familiar one for the ordinary transform, which provides a convenient technique for solving certain classes of ordinary and partial differential equations which arise in quantum mechanics from classical quadratic hamiltonians.
Journal ArticleDOI
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.
Journal ArticleDOI
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.