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基于物联网的水相关疾病预测自动化系统。

IoT-based automated system for water-related disease prediction.

机构信息

Shree L.R. Tiwari Engineering College, Mumbai University, Mumbai, India.

Researcher, ICICI Lombard GIC Ltd, Mumbai, India.

出版信息

Sci Rep. 2024 Nov 27;14(1):29483. doi: 10.1038/s41598-024-79989-6.

DOI:10.1038/s41598-024-79989-6
PMID:39604479
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11603214/
Abstract

Having access to potable water is a fundamental right to well-being. Despite this, 3.4 million people die from diseases caused by water each year, and 1.1 billion people lack access to potable drinking water. Although industrialization, durable infrastructure, and rapid development have increased living standards, the water problem has left humanity defenseless. As different human activities have contaminated these water reserves, according to an estimate, water is the cause of 80% of ailments. As a result, it is necessary to permit enough infrastructure to ensure the security of a reliable supply of potable water. Thus, a real-time WBPCB dataset with 17 features and a proposed IoT-based system to collect data are used in this research to address the issue. The research paper provides a system for predicting diseases and forecasting long-term trends. Classification is performed using Random Forest, XGBoost, and AdaBoost, which have accuracy rates of 99.66%, 99.52%, and 99.64%, respectively. Forecasting is performed using LSTM, which has an MSE value for the pH parameter of 0.1631. The paper introduces TS-SMOTE, a novel hybridized time-series SMOTE data augmentation approach. Additionally, it offers an IoT system that uses H-ANFIS to gather data in real-time and identify attacks.

摘要

获得饮用水是福祉的基本权利。尽管如此,每年仍有 340 万人死于水引发的疾病,11 亿人无法获得饮用水。尽管工业化、耐用基础设施和快速发展提高了生活水平,但水问题却使人类束手无策。由于人类的不同活动污染了这些水资源储备,据估计,水是 80%疾病的根源。因此,有必要允许足够的基础设施来确保可靠的饮用水供应安全。因此,本研究使用具有 17 个特征的实时 WBPCB 数据集和提出的基于物联网的系统来收集数据,以解决这个问题。本研究论文提供了一种用于预测疾病和预测长期趋势的系统。使用随机森林、XGBoost 和 AdaBoost 进行分类,准确率分别为 99.66%、99.52%和 99.64%。使用 LSTM 进行预测,其 pH 参数的均方误差值为 0.1631。本文介绍了 TS-SMOTE,一种新颖的混合时间序列 SMOTE 数据增强方法。此外,它还提供了一个物联网系统,该系统使用 H-ANFIS 实时收集数据并识别攻击。

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