Papers
Topics
Authors
Recent
Search
2000 character limit reached

A metaplectic perspective of uncertainty principles in the Linear Canonical Transform domain

Published 17 May 2024 in math.FA, math-ph, math.MP, and quant-ph | (2405.10651v1)

Abstract: We derive Heisenberg uncertainty principles for pairs of Linear Canonical Transforms of a given function, by resorting to the fact that these transforms are just metaplectic operators associated with free symplectic matrices. The results obtained synthesize and generalize previous results found in the literature, because they apply to all signals, in arbitrary dimension and any metaplectic operator (which includes Linear Canonical Transforms as particular cases). Moreover, we also obtain a generalization of the Robertson-Schr\"odinger uncertainty principle for Linear Canonical Transforms. We also propose a new quadratic phase-space distribution, which represents a signal along two intermediate directions in the time-frequency plane. The marginal distributions are always non-negative and permit a simple interpretation in terms of the Radon transform. We also give a geometric interpretation of this quadratic phase-space representation as a Wigner distribution obtained upon Weyl quantization on a non-standard symplectic vector space. Finally, we derive the multidimensional version of the Hardy uncertainty principle for metaplectic operators and the Paley-Wiener theorem for Linear Canonical Transforms.

Definition Search Book Streamline Icon: https://streamlinehq.com
References (25)
  1. L. Cohen, Generalized phase-space distribution functions. Journal of Mathematical Physics 7 (1966) 781-786.
  2. E. Cordero and L. Rodino,Wigner Analysis of Operators: Part I Pseudodifferential Operators and Wave Front Sets. Applied and Computational Harmonic Analysis 58 (2022) 85-123.
  3. E. Cordero and L. Rodino, Characterization of modulation spaces by symplectic representations and applications to Schrödinger equations. Journal Functional Analysis 284 (2023) 109892.
  4. N.C. Dias and J.N. Prata, Wigner functions on non-standard symplectic vector spaces. Journal of Mathematical Physics 59 (2018) 012108.
  5. J.J. Ding and S.C. Pei, Heisenberg’s uncertainty principles for the 2-d nonseparable linear canonical transforms. Signal Processing 93 (5) (2013) 1027-1043.
  6. G.B. Folland and A. Sitaram, The uncertainty principle: A mathematical survey. Journal of Fourier Analysis and Applications 3 (3) (1997) 207-238.
  7. G.B. Folland, Harmonic analysis in phase space. Princeton University Press (1989).
  8. M. de Gosson. Symplectic Methods in Harmonic Analysis and in Mathematical Physics. Birkhäuser, Basel (2011).
  9. M. de Gosson. Symplectic Geometry and Quantum Mechanics, Birkhäuser, Basel, series “Operator Theory: Advances and Applications” (subseries: “Advances in Partial Differential Equations”), Vol. 166 (2006)
  10. M. de Gosson, Symplectic Radon transform and the metaplectic representation. Entropy 24 (2022) 761.
  11. V. Guillemin and S. Sternberg. Symplectic techniques in physics. Cambridge university press, 1990.
  12. G. H. Hardy, A theorem concerning Fourier transforms. Journal of the London Mathematical Society 8 (1933) 227–231.
  13. W. Heisenberg, Über den anschaulischen Inhalt der quantentheoretischen Kinematik und Mechanik. Zeitschrift für Physik 43 (1927) 172.
  14. R.L. Hudson, When is the Wigner quasi-probability density nonnegative? Reports on Mathematical Physics 6 (1974) 249-252.
  15. P. Jaming, A simple observation on the uncertainty principle for the fractional Fourier transform. Journal of Fourier Analysis and Applications 28 (2022) 51.
  16. E.H. Kennard, Zur Quantenmechanik einfacher Bewegungstypen. Zeitschrift für Physik 44 (1927) 326.
  17. J.M. Maillard, On the twisted convolution product and the Weyl transformation of tempered distributions. Journal of Geometry and Physics 3(2) (1986) 232-261.
  18. V. Namias, The fractional order Fourier transform and its application to quantum mechanics. IMA Journal of Applied Mathematics 25 (1980) 241–265.
  19. H. Robertson, The uncertainty principle. Physical Review 34 (1929) 163.
  20. K.K. Sharma and S.D. Joshi, Uncertainty principle for real signals in the linear canonical transform domains. IEEE Transactions on Signal Processing 56 (7) (2008) 2677-2683.
  21. A. Stern, Uncertainty principles in linear canonical transform domains and some of their implications in optics. Journal of the Optical Society of America A 25 (2008) 647–652.
  22. Y. Yang and K.I. Kou, Uncertainty principles for hyper complex signals in the linear canonical transform domains. Signal Processing 95 (2) (2014) 67-75.
  23. Z.C. Zang, Tighter uncertainty principles for linear canonical transform in terms of matrix decomposition. Digital Signal Processing 69 (10) (2017) 70-85.
  24. Z. Zhang, Uncertainty principle of complex-valued functions in specific free metaplectic transformation domains. Journal of Fourier Analysis and Applications 27 (2021) 68.
  25. Z. Zhang, Uncertainty principle for real functions in free metaplectic transformation domains. Journal of Fourier Analysis and Applications 25 (2019) 2899.
Citations (1)
View on Semantic Scholar

Summary

No one has generated a summary of this paper yet.

Sign Up to Summarize

Paper to Video (Beta)

No one has generated a video about this paper yet.

Sign Up to Generate All Videos Subscribe on YouTube

Whiteboard

No one has generated a whiteboard explanation for this paper yet.

Sign Up to Generate

Open Problems

We haven't generated a list of open problems mentioned in this paper yet.

Generate Now

Continue Learning

We haven't generated follow-up questions for this paper yet.

Generate Now

Collections

Sign up for free to add this paper to one or more collections.

Sign Up

Tweets

Sign up for free to view the 1 tweet with 0 likes about this paper.

Sign Up for Free