RECONSTRUCTION OF THE CORNEAL SURFACE OF THE HUMAN EYE USING A COMPUTATIONAL EVOLUTIONARY ALGORITHM. PRACTICAL APPLICATION IN NON-PATHOLOGICAL CASES

IF 0.8 4区 工程技术 Q3 ENGINEERING, MULTIDISCIPLINARY
Dyna Pub Date : 2024-01-01 DOI:10.6036/10998
Francisco CAVAS MARTINEZ, Francisco Luis SAEZ GUTIERREZ, José Sebastián VELÁZQUEZ BLÁZQUEZ, Jorge L. Alió, J. L. Alio del Barrio
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引用次数: 0

Abstract

Increasingly, the use of geometric modelling techniques in Applied Ophthalmology is significant in the characterization of important pathologies of the cornea, such as Keratoconus. This article presents a novel method for the geometric reconstruction of the corneal surface from optical topography using a genetic algorithm. Traditionally, mathematical programming methods such as the least squares method have been used to obtain the coefficients of the corneal surface function, such as Navarro model or Zernike polynomials. This new method uses non-dominated multivariable genetic algorithm optimization to obtain the surface function coefficients from the point cloud obtained with corneal topographer device. Once the reconstruction is performed, the surface is represented using CAD software, and morphogeometric parameters are obtained. The experimental sample consisted in 33 healthy patients eyes, aged from 11 to 63, and without previous ocular surgeries or pathologies. Topographic data were obtained using a Scheimpflug Sirius tomographer (CSO, Italy). The computational optimization was executed under Matlab software environment (Mathworks, USA). The new method provides a lower mean squared error (MSE) than those obtained by the least squares or the nonlinear programming algorithms. Thus, the morphogeometric parameters obtained from the patient's corneas fit better, allowing for a better analysis of real clinical conditions.
利用计算进化算法重建人眼角膜表面。在非病理情况下的实际应用
在应用眼科学中,几何建模技术的使用越来越多,这对角膜重要病变(如角膜炎)的定性具有重要意义。本文介绍了一种利用遗传算法从光学地形图重建角膜表面几何模型的新方法。传统上,人们使用最小二乘法等数学编程方法来获取角膜表面函数的系数,如纳瓦罗模型或 Zernike 多项式。这种新方法采用非支配多变量遗传算法优化,从角膜地形图仪获得的点云中获取表面函数系数。重建完成后,用 CAD 软件表示表面,并获得形态计量参数。实验样本包括 33 名健康患者的眼睛,年龄从 11 岁到 63 岁不等,既往未接受过眼部手术,也没有病变。地形图数据通过 Scheimpflug Sirius 层析成像仪(意大利 CSO 公司)获得。计算优化在 Matlab 软件环境下进行(Mathworks,美国)。与最小二乘法或非线性编程算法相比,新方法的均方误差(MSE)更小。因此,从患者角膜上获得的形态计量参数更加吻合,从而可以更好地分析真实的临床情况。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Dyna
Dyna 工程技术-工程:综合
CiteScore
1.00
自引率
10.00%
发文量
131
审稿时长
6-12 weeks
期刊介绍: Founded in 1926, DYNA is one of the journal of general engineering most influential and prestigious in the world, as it recognizes Clarivate Analytics. Included in Science Citation Index Expanded, its impact factor is published every year in Journal Citations Reports (JCR). It is the Official Body for Science and Technology of the Spanish Federation of Regional Associations of Engineers (FAIIE). Scientific journal agreed with AEIM (Spanish Association of Mechanical Engineering) In character Scientific-technical, it is the most appropriate way for communication between Multidisciplinary Engineers and for expressing their ideas and experience. DYNA publishes 6 issues per year: January, March, May, July, September and November.
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