基于 ANN 的预测技术在极小生物医学数据分析中的改进

I. Izonin, R.O. Tkachenko, O. Berezsky, Iurii Krak, Michal Kováč, M. Fedorchuk
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摘要

如今,生物医学工程领域横跨众多科学研究领域,这些领域都面临着对小型数据集进行智能分析的挑战。利用现有的人工智能工具分析这些数据集是一项复杂的任务,而过拟合等问题以及机器学习方法和人工神经网络所固有的其他挑战往往使这项任务变得更加复杂。这些挑战严重制约了这些工具在实际应用中解决手头问题的能力。虽然数据扩增可以提供一些缓解措施,但现有方法往往会引入自身的一系列局限性,降低解决问题的整体效率。在本文中,作者提出了一种基于神经网络的改进技术,用于在分析小型和超小型数据集时预测结果。这种方法以输入加倍法为基础,利用响应面线性化原理来提高性能。本文提供了改进技术操作的详细流程图,同时还介绍了拟议解决方案的新准备和应用算法。建模使用了两个生物医学数据集,并通过微分进化选择了最佳参数,结果显示预测准确率很高。与现有的几种方法进行比较后发现,各种误差明显减少,这凸显了改进后的神经网络技术在分析极小的生物医学数据集方面的优势,而且无需训练。
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Improvement of the ANN-Based Prediction Technology for Extremely Small Biomedical Data Analysis
Today, the field of biomedical engineering spans numerous areas of scientific research that grapple with the challenges of intelligent analysis of small datasets. Analyzing such datasets with existing artificial intelligence tools is a complex task, often complicated by issues like overfitting and other challenges inherent to machine learning methods and artificial neural networks. These challenges impose significant constraints on the practical application of these tools to the problem at hand. While data augmentation can offer some mitigation, existing methods often introduce their own set of limitations, reducing their overall effectiveness in solving the problem. In this paper, the authors present an improved neural network-based technology for predicting outcomes when analyzing small and extremely small datasets. This approach builds on the input doubling method, leveraging response surface linearization principles to improve performance. Detailed flowcharts of the improved technology’s operations are provided, alongside descriptions of new preparation and application algorithms for the proposed solution. The modeling, conducted using two biomedical datasets with optimal parameters selected via differential evolution, demonstrated high prediction accuracy. A comparison with several existing methods revealed a significant reduction in various errors, underscoring the advantages of the improved neural network technology, which does not require training, for the analysis of extremely small biomedical datasets.
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