论文信息 - Optimized visualization of phase objects with semiderivative real filters

Optimized visualization of phase objects with semiderivative real filters

There is a need for a frequency-domain real filter that visualizes pure-phase objects with thickness either considerably smaller or much bigger than 2π rad and gives output image irradiance proportional to the first derivative of object phase function for a wide range of phase gradients. We propose to construct a nonlinearly graded filter as a combination of Foucault and the square-root filters. The square root filter in frequency plane corresponds to the semiderivative in object space. Between the two half-planes with binary values of amplitude transmittance a segment with nonlinearly varying transmittance is located. Within this intermediate sector the amplitude transmittance is given with a biased antisymmetrical function whose positive and negative frequency branches are proportional to the square-root of spatial frequencies contained therein. Our simulations show that the modified square root filter visualizes both thin and thick pure phase objects with phase gradients from 0.6π up to more than 60π rad/mm.

Tomasz Szoplik | Arkadiusz Sagan | Marek Kowalczyk

[1] Marek Kowalczyk. Spectral and imaging properties of uniform diffusers , 1984 .

[2] Jeffrey A. Davis,et al. Selective edge enhancement of images with an acousto-optic light modulator. , 2002, Applied optics.

[3] M. Fernández-Alonso,et al. Fractional derivative Fourier plane filter for phase-change visualization. , 1997, Applied optics.

[4] T Szoplik,et al. Phase-change visualization in two-dimensional phase objects with a semiderivative real filter. , 1998, Applied optics.

[5] H. Furuhashi,et al. Visualization of phase objects by use of a differentiation filter. , 2003, Applied optics.

[6] Thomas J. Osler,et al. Fractional Derivatives and Special Functions , 1976 .

[7] H Kasprzak,et al. Differentiation of a noninteger order and its optical implementation. , 1982, Applied optics.

[8] B A Horwitz. Phase image differentiation with linear intensity output. , 1978, Applied optics.

[9] J Campos,et al. Fractional derivatives-analysis and experimental implementation. , 2001, Applied optics.

[10] R A Sprague,et al. Quantitative visualization of large variation phase objects. , 1972, Applied optics.

[11] Tomasz Szoplik,et al. Phase-object fractional differentiation using Fourier plane filters , 1997 .

[12] Tomasz Szoplik,et al. Visualization of phase objects with real semiderivative and schlieren filters: a comparison , 2003, Polish-Slovak-Czech Optical Conference on Wave and Quantum Aspects of Contemporary Optics.