David Carmona-Ballester scite author profile

David Carmona-Ballester

13Publications

24Citation Statements Received

94Citation Statements Given

How they've been cited

How they cite others

194

Affiliations

University of La Laguna, TiGenix (Spain)

Publications

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Influence of angle Kappa on the optimal intraocular orientation of asymmetric multifocal intraocular lenses

Bonaque-González

Jaskulski

Carmona-Ballester

et al. 2021

Journal of Optometry

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Purpose to evaluate the effects of kappa angle and intraocular orientation on the theoretical performance of asymmetric multifocal intraocular lenses (MIOL). Methods For a total of 21 corneal aberrations, a computational analysis simulated the implantation of a computationally designed MIOL. An image quality parameter (IQ) (visually modulated transfer function metric) was calculated for a 5.0-mm pupil and for three conditions: distance, intermediate, and near vision. The procedure was repeated for each eye after a rotation of the MIOL with respect to the cornea from 0º to 360º in 5º steps. Kappa angles from 0 to 900 microns, in 150 microns steps, combined with two two variants of MIOL centration were tested: in the corneal apex or in the center of the entrance pupil. A p-value ≤ 0.05 was considered significant. Results There were statistically significant differences of the IQ depending of the intraocular orientation of the MIOL. If kappa angle was increased, there was a statistically significant decrease of the IQ. The IQ maintained stable when the optimal intraocular orientation was re-calculated for each kappa angle. In general, the inter-variability of the results between subjects was very high. There were no strong evidences supporting that there exists a preferable centration point. Conclusions Our results suggest that kappa angle theoretically affects significantly the performance of asymmetric MIOL implantation. However, its negative effect can be compensated if a customized intraocular orientation is calculated taking into account the presence of the kappa angle.

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New high-resolution wave front sensing ophthalmic technique for the characterization of ocular optics

Bonaque-González

Trujillo-Sevilla

Casanova-González

et al. 2020

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Weighted nonnegative tensor factorization for atmospheric tomography reconstruction

Carmona-Ballester

Trujillo-Sevilla²,

Bonaque-González³

et al. 2018

A&A

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Context. Increasing the area on the sky over which atmospheric turbulences can be corrected is a matter of wide interest in astrophysics, especially when a new generation of extremely large telescopes (ELT) is to come in the near future. Aims. In this study we tested if a method for visual representation in three-dimensional displays, the weighted nonnegative tensor factorization (WNTF), is able to improve the quality of the atmospheric tomography (AT) reconstruction as compared to a more standardized method like a randomized Kaczmarz algorithm. Methods. A total of 1000 different atmospheres were simulated and recovered by both methods. Recovering was computed for two and three layers and for four different constellations of laser guiding stars (LGS). The goodness of both methods was tested by means of the radial average of the Strehl ratio across the field of view of a telescope of 8m diameter with a sky coverage of 97.8 arcsec. Results. The proposed method significantly outperformed the Kaczmarz in all tested cases (p ≤ 0.05). In WNTF, three-layers configuration provided better outcomes, but there was no clear relation between different LGS constellations and the quality of Strehl ratio maps. Conclusions. The WNTF method is a novel technique in astronomy and its use to recover atmospheric turbulence profiles was proposed and tested. It showed better quality of reconstruction than a conventional Kaczmarz algorithm independently of the number and height of recovered atmospheric layers and of the constellation of laser guide star used. The WNTF method was shown to be a useful tool in highly ill-posed AT problems, where the difficulty of classical algorithms produce high Strehl value maps.

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Analyzing the impact of the initialization for the nonnegative tensor factorization in tensor displays

et al. 2018

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Reconstructing wavefront phase from measurements of its slope, an adaptive neural network based approach

Ceruso

Bonaque-González

Ríos

et al. 2020

Optics and Lasers in Engineering

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Focus measurement in 3D focal stack using direct and inverse discrete radon transform

Gómez-Cárdenes

Marichal-Hernández

Trujillo-Sevilla

et al. 2017

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Calibration method applied to a tunable tensor display system

Carmona-Ballester

Guadalupe-Suárez

Trujillo-Sevilla

et al. 2019

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Optical and physics differential characteristics of optical plastics

et al. 2018

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Optical organic materials, or optical plastics, are raising interest in recent decades thanks to advances in manufacturing processes. It is already common for these materials to be in optical systems, for example in the field of medicine or computer science. However, the characteristics of these compounds have not been as studied as in the case of glasses, and the little available information is widely dispersed. The present revision article tries to compile those most interesting optical and physics differential characteristics of the optical plastics, from the point of view of an optical engineer which must face the design of an optical system.

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