论文信息 - Understanding superresolution in Wigner space.

Understanding superresolution in Wigner space.

Superresolution permits fine details to be observed that cannot be resolved by standard optical instruments. We demonstrate that superresolution is nothing more than an adaptation of degrees of freedom converted from the spatial domain to some other domains and vice versa. The tool used for the required conversion and adaptation is the Wigner chart. In addition, we show that the Wigner chart may be naturally applied for analyzing and understanding complex optical setups used for obtaining superresolution.

D Mendlovic | A W Lohmann | Z Zalevsky

[1] M. FranÇon. Contribution à l’amélioration du pouvoir séparateur , 1952 .

[2] A. Lohmann. Image rotation, Wigner rotation, and the fractional Fourier transform , 1993 .

[3] H. Dammann,et al. High-efficiency in-line multiple imaging by means of multiple phase holograms , 1971 .

[4] G. D. Francia. Resolving Power and Information , 1955 .

[5] David Mendlovic,et al. Space–bandwidth product adaptation and its application to superresolution: fundamentals , 1997 .

[6] W. Gärtner,et al. Ein Experiment zur Überschreitung der Abbeschen Auflösungsgrenze , 1963 .

[7] A. W. Lohmann,et al. Optical processing of one-dimensional signals , 1982 .

[8] G. D. Francia. Degrees of Freedom of Image , 1969 .

[9] Zeev Zalevsky,et al. Super resolution optical systems for objects with finite sizes , 1999 .

[10] W. Lukosz. Optical Systems with Resolving Powers Exceeding the Classical Limit , 1966 .

[11] Z. Zalevsky,et al. Generalized Wigner function for the analysis of superresolution systems. , 1998, Applied optics.

[12] D Mendlovic,et al. Wavelength-multiplexing system for single-mode image transmission. , 1997, Applied optics.

[13] Zeev Zalevsky,et al. Space–bandwidth product adaptation and its application to superresolution: examples , 1997 .