Two-Dimensional Nonseparable Fractional Fourier Transform: Theory and Application
Abstract
The one-dimensional (1D) fractional Fourier transform (FRFT) generalizes the 1D Fourier transform, offering significant advantages in time-frequency analysis of non-stationary signals. To extend the benefits of the 1D FRFT to higher-dimensional signals, 2D FRFTs, such as the 2D separable FRFT (SFRFT), gyrator transform (GT), and coupled FRFT (CFRFT), have been developed. However, existing 2D FRFTs suffer from several limitations: (1) a lack of theoretical uniformity and general applicability, (2) an inability to handle 2D non-stationary signals with nonseparable terms, and (3) failure to maintain a consistent 4D rotational relationship with the 2D Wigner distribution (WD), which is essential for ensuring geometric consistency and symmetry in time-frequency analysis. These limitations restrict the methods' performance in practical applications, such as radar, communication, sonar, and optical imaging, in which nonseparable terms frequently arise. To address these challenges, we introduce a more general definition of the 2D FRFT, termed the 2D nonseparable FRFT (NSFRFT). The 2D NSFRFT has four degrees of freedom, includes the 2D SFRFT, GT, and CFRFT as special cases, and maintains a more general 4D rotational relationship with the 2D WD. We derive its properties and present three discrete algorithms, two of which are fast algorithms with computational complexity $O(N^2 \log N)$ comparable to that of the 2D SFRFT. Numerical simulations and experiments demonstrate the superior performance of the 2D NSFRFT in applications such as image encryption, decryption, filtering, and denoising.