大规模机器通信与时间卷积网络融合的mTCN灾害预测框架设计。

IF 3.9 2区综合性期刊 Q1 MULTIDISCIPLINARY SCIENCES

Scientific Reports Pub Date : 2025-08-10 DOI:10.1038/s41598-025-15397-8

M Umadevi, J Arun Kumar, S Vishnu Priyan, C Vivek

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引用次数: 0

摘要

洪水、海啸和地震等自然灾害严重影响人们的生活和基础设施，因此迫切需要准确和实时的预测系统。当前的方法通常在可伸缩性、隐私性和实时数据集成方面受到限制，特别是在大规模灾难场景中。本研究介绍了mTCN-FChain框架，这是一种将大规模机器类型通信（mMTC）和时间卷积网络（TCNs）与联邦学习和区块链技术相结合的新颖解决方案。目标是开发一个可扩展、安全、高效的系统，用于使用物联网数据流进行实时灾难预测。轻量级的基于边缘的tcn支持局部异常检测，而联邦学习确保了跨边缘设备的隐私保护协作模型训练。区块链集成保护模型更新并提供可跟踪性。使用地震、洪水和海啸的数据集，该框架在Python中实现，并使用MAE、MSE和RMSE等指标进行验证。结果表明，与现有方法相比，该方法的性能有了显著提高，在灾难预测任务中具有更高的准确性、更低的延迟和强大的可伸缩性。使用了TensorFlow、PyTorch和Hyperledger Fabric等工具来实现。该研究的结论是，mTCN-FChain提供了一种变革性的抗灾方法，尽管未来的工作将侧重于优化区块链集成和扩大现实世界的适用性，以增强其稳健性和适应性。

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Design of mTCN framework for disaster prediction a fusion of massive machine type communications and temporal convolutional networks.

Natural disasters such as floods, tsunamis, and earthquakes significantly impact lives and infrastructure, highlighting the urgent need for accurate and real-time prediction systems. Current methods often suffer from limitations in scalability, privacy, and real-time data integration, particularly in large-scale disaster scenarios. This study introduces the mTCN-FChain framework, a novel solution that combines Massive Machine-Type Communications (mMTC) and Temporal Convolutional Networks (TCNs) with federated learning and blockchain technology. The objective is to develop a scalable, secure, and efficient system for real-time disaster prediction using IoT data streams. Lightweight edge-based TCNs enable localized anomaly detection, while federated learning ensures privacy-preserving collaborative model training across edge devices. Blockchain integration secures model updates and provides traceability. Using datasets for earthquakes, floods, and tsunamis, the framework was implemented in Python and validated using metrics such as MAE, MSE, and RMSE. The results show significant performance improvements over existing methods, with higher accuracy, reduced latency, and robust scalability in disaster prediction tasks. Tools like TensorFlow, PyTorch, and Hyperledger Fabric were employed for implementation. The study concludes that mTCN-FChain offers a transformative approach to disaster resilience, though future work will focus on optimizing blockchain integration and expanding real-world applicability to enhance its robustness and adaptability.

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来源期刊

Scientific Reports Natural Science Disciplines-

CiteScore

7.50

自引率

4.30%

发文量

19567

审稿时长

3.9 months

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