基于高级深度学习和卷积神经网络的增强型肺癌识别与分类技术

Ammar Hassan, Hamayun Khan, Arshad Ali, Irfan Ud Din, Abdullah Sajid, Mohammad Husain, Muddassar Ali, Amna Naz, Hanfia Fakhar
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引用次数: 0

摘要

本研究提出了一种基于新型深度学习技术的快速、准确、稳定的肺癌检测系统。肺癌仍然是全球最严重的健康问题之一,因此迫切需要低成本、无创的筛查方法。尽管最常用的诊断方法包括 CT 扫描、X 光等。人眼的判读方法各不相同,难免会出现误差。为了应对这一挑战,我们概述了一种基于深度学习模型的更加自动化的方法,可用于对肺部图片进行高精度分类。这项研究利用了一个庞大的肺部扫描数据集,分为正常、恶性和良性。初看这些数据,发现它们与图片大小和类别差异有一定的关联。意识到实时传输需要持续输入,每张图片都经过了灰度转换和降维处理。为了有效处理研究中发现的数据集的不均衡性,我们采用了合成少数群体过度取样技术(SMOTE)。在本报告中,介绍了三种新的设计:模型 I、模型 2 和模型 3。此外,还开发了一个架构,目的是合并所有三个模型的预测结果。此外,在所有创建的模型中,最佳模型为模型 1,准确率约为 84%。7%.但是,旨在使每个模型都达到最佳效果的集合策略却产生了惊人的 82.5% 的准确率。模型 2 和模型 3 的具体优势和误分类行为虽然不如模型 1 准确,但目前正在进行评估,以便在未来对模型集合进行改进。利用深度学习开发的技术以更快、更高效、无接触的方式解决了肺癌分析所面临的挑战。事实上,它能够与其他诊断仪器协同工作,这有助于减少诊断错误,加强对患者的护理。我们已经解决了这一问题,因此不同的从业人员都能读到这篇论文,我们也能走向下一代诊断技术。
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An Enhanced Lung Cancer Identification and Classification Based on Advanced Deep Learning and Convolutional Neural Network
In this research, a fast, accurate, and stable system of lung cancer detection based on novel deep learning techniques is proposed. Lung cancer continues to be one of the most monumental global health concerns, which is why there is an urgent need for low-cost and non-invasive screening. Though the diagnostic methods that are most commonly in use include CTscan, X-ray etc. The interpretation by the human eye varies and errors are bound to occur. In response to this challenge, we outline a more automated approach that is based on deep learning models and can be used to classify lung pictures with high levels of accuracy. This research makes use of a large data set of lung scans categorised as normal, malignant, and benign. The first look what the data had in store threw up some correlation with picture size and what seemed to be category differences. Realizing that live feed requires constant input, each picture underwent grayscale conversion and dimensionality reduction. In order to effectively deal with the unbalanced nature of the dataset that was discovered in the study, the Synthetic Minority Oversampling Technique (SMOTE) was applied as a technique. In this presentation, three new designs were introduced: Model I, Model 2, and Model 3. Additionally, one architecture was developed with the purpose of merging the predictions of all three models. Furthermore, out of all the models created, the best model emerged as model 1 with approximately an accuracy of 84%. 7%. But the ensemble strategy which was intended to make the best of each of the models, produced an astounding 82. 5% accuracy. The specific advantages and misclassification behaviors of Model 2 and 3, although less accurate than Model 1 but are currently under evaluation for future Model ensemble improvements. The technique developed using deep learning addresses the challenges at a faster, efficient, and contactless approach to lung cancer analysis. The fact that it is capable of operating in tandem with others diagnostic instruments may help reduce diagnostic errors and enhance patient care. We have addressed this issue so that the various practitioners would be able to read this paper and we can go to the next generation of diagnostic technologies.
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