基于卷积神经网络的疟疾疾病预测

Dhrgam Al Kafaf, Noor N. Thamir, Samara S. AL-Hadithy
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引用次数: 0

摘要

本研究通过检查细胞图像,深入研究卷积神经网络(CNN)在识别疟疾方面的功效。所采用的数据集包括从 Kaggle 上著名的疟疾细胞图像数据集中获取的共计 27,558 张图像,其中包含各种性质的细胞。CNN 模型的架构经过精心设计,由六个区块和三个相互连接的区块组成,从而实现了高效的特征提取和随后的细胞分类。创造性解析:我们巧妙地利用了各种策略,如丢弃、批量归一化和全局平均池化,来完善和强化模型,确保其稳健性和适应性。为了应对梯度递减的挑战并促进收敛,我们巧妙地采用了被称为整流线性单元(ReLU)的激活函数。通过困惑度网格对模型的有效性进行评估后得出了结果。该模型的精确率为 99.59%,特异性为 99.69%,灵敏度为 99.40%,F1 测量值为 99.44%,精确度为 99.48,显示了其有效区分疟疾感染细胞和未感染细胞的能力。这项研究的重点强调了 CNN 在利用图像分析促进疟疾自动识别方面的巨大潜力。通过利用其独特的架构和正则化技术,CNNs 有能力提高结果,并有可能在疟疾流行地区带来更好的结果。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Malaria Disease Prediction Based on Convolutional Neural Networks
This study delves into the investigation of the efficacy of Convolutional Neural Networks (CNNs) in identifying malaria through the examination of cell images. The dataset employed encompasses a total of 27,558 images, harvested from the renowned Malaria Cell Images Dataset on Kaggle, encompassing cells of diverse nature. The architectonics of the CNN model is meticulously devised, comprising of six blocks and three interconnected blocks, thereby rendering an efficient extraction of features and subsequent classification of the cells. Creative paraphrasing: Various strategies such as dropout, batch normalization, and global average pooling are artfully utilized to refine and fortify the model, ensuring its robustness and adaptability. In order to confront the challenge of diminishing gradient and facilitate the attainment of convergence, the activation function known as Rectified Linear Unit (ReLU) is ingeniously employed. Assessing the efficacy of the model via a perplexity grid produces outcomes. Exhibiting a precision rate of 99.59%, a specificity measure of 99.69%, an Sensitivity of 99.40%, F1 Measurement of 99.44%, and a Precision of 99.48, it showcases its capacity to effectively distinguish betwixt malaria-afflicted cells and unafflicted cells. The focal point of this research highlights the substantial potential of CNNs in facilitating the automated identification of malaria using image analysis. By harnessing their unique architecture and regularization techniques, CNNs have the capability to enhance the results and potentially bring about better outcomes in areas with prevalent cases of malaria.
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