利用神经网络对红细胞平衡形态的有效识别

Pub Date : 2021-06-01 DOI:10.32523/2306-6172-2021-9-2-39-56

Houda Fahim, Olivier Sawadogo, N. Alaa, M. Guedda

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引用次数: 0

摘要

这项生物物理中具有界面的应用数学工作专注于单个红细胞形状的形状识别和数值建模。这项工作的目的是提供一种定量方法来解释显微镜下红细胞形状的实验观察结果。在本文中，我们基于经典的几何形状最小化理论给出了一个新的公式，该公式假设具有附加约束的曲率能量控制红细胞的形状。为了在体积和面积约束下最小化这种能量，我们提出了一种新的混合算法，该算法结合了粒子群优化（PSO）、引力搜索（GSA）和神经网络算法（NNA）。使用该新算法获得的结果与Evans等人给出的实验结果非常一致。（8）特别是对于球形和双凹面形状。

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AN EFFICIENT IDENTIFICATION OF RED BLOOD CELL EQUILIBRIUM SHAPE USING NEURAL NETWORKS

This work of applied mathematics with interfaces in bio-physics focuses on the shape identification and numerical modelisation of a single red blood cell shape. The purpose of this work is to provide a quantitative method for interpreting experimental observations of the red blood cell shape under microscopy. In this paper we give a new formulation based on classical theory of geometric shape minimization which assumes that the curvature energy with additional constraints controls the shape of the red blood cell. To minimize this energy under volume and area constraints, we propose a new hybrid algorithm which combines Particle Swarm Optimization (PSO), Gravitational Search (GSA) and Neural Network Algorithm (NNA). The results obtained using this new algorithm agree well with the experimental results given by Evans et al. (8) especially for sphered and biconcave shapes.

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