Digital in-line holography assessment for general phase and opaque particle

Abstract: We propose using the circle polynomials to describe a particle's transmission function in a digital holography setup. This allows both opaque and phase particles to be determined. By means of this description, we demonstrate that it is possible to estimate the digital in-line hologram produced by a spherical particle. The experimental intensity distribution due to an opaque micro-inclusion is compared to the theoretical one obtained by our new model. Moreover, the simulated hologram and reconstructed image of … Show more

“…Otherwise, when n d < n b , total reflexion does not occur. This point has been developed in [6] in the case of a transparent particle as inclusion. In the case of [6], a general pupil function, denoted by p(s, θ), represented in the form of a Zernike series:…”

“…Then, the expansion coefficients γ m n are used to determine the expansion coefficients Γ m n (ε). The summation is over n = |m|, |m| + 2, · · · , n. This way of writing the scaled pupil function allows us to use the previous developments in [6]. Consequently, the intensity distribution I(σ) recorded by the CCD satisfies…”

“…In this paragraph, two cases have been considered: in the first case, the air bubble is approximated as a thin lens, ie, a quadratic phase approximation, and the second case, the air bubble is approximated as a quasi-spherical phase approximation. To elaborate the new expressions of the Zernike coefficients of the two cited cases, the Zernike coefficients in [6] for a transparent particle are used.…”

“…Now, if the quasi-spherical approximation is employed [6,21] to describe the pupil function p of the air bubble, recall that in the case of [6] …”

“…Probably, this impossibility is essentially due to the chosen experimental configuration. Recently, in the case of holography, we have proposed a modelisation of a droplet in the air to calculate the hologram of such an object [6]. In that study, the aperture, i.e., the ratio between the index of the air and the index of the droplet, is no more than unity.…”

Digital in-line holography in a droplet with cavitation air bubbles

“…Otherwise, when n d < n b , total reflexion does not occur. This point has been developed in [6] in the case of a transparent particle as inclusion. In the case of [6], a general pupil function, denoted by p(s, θ), represented in the form of a Zernike series:…”

“…Then, the expansion coefficients γ m n are used to determine the expansion coefficients Γ m n (ε). The summation is over n = |m|, |m| + 2, · · · , n. This way of writing the scaled pupil function allows us to use the previous developments in [6]. Consequently, the intensity distribution I(σ) recorded by the CCD satisfies…”

“…In this paragraph, two cases have been considered: in the first case, the air bubble is approximated as a thin lens, ie, a quadratic phase approximation, and the second case, the air bubble is approximated as a quasi-spherical phase approximation. To elaborate the new expressions of the Zernike coefficients of the two cited cases, the Zernike coefficients in [6] for a transparent particle are used.…”

“…Now, if the quasi-spherical approximation is employed [6,21] to describe the pupil function p of the air bubble, recall that in the case of [6] …”

“…Probably, this impossibility is essentially due to the chosen experimental configuration. Recently, in the case of holography, we have proposed a modelisation of a droplet in the air to calculate the hologram of such an object [6]. In that study, the aperture, i.e., the ratio between the index of the air and the index of the droplet, is no more than unity.…”

Digital in-line holography in a droplet with cavitation air bubbles

Simultaneous amplitude and phase contrast imaging of burning fuel particle and flame with digital inline holography: Model and verification

T-matrix methods for electromagnetic structured beams: A commented reference database for the period 2014–2018