基于TinyMLt的铁路隧道沉降数据流处理优化低功耗智能系统设计

IF 4 3区计算机科学 Q1 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE

Computers & Electrical Engineering Pub Date : 2025-03-07 DOI:10.1016/j.compeleceng.2025.110197

Baihang Lv , Lei Wang , Xing Liu , Bin Liu , Bo Liu , Ziwen Zhang , Yang Li , Fangzhe Shi

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引用次数: 0

摘要

TinyML技术的进步为设计低功耗智能系统开辟了新的途径，显著增强了关键基础设施中嵌入式设备的处理能力。为了克服这些限制，我们提出了一个动态地质力学预测框架（DGPF）与一种新的自适应学习信息模拟（ALIS）策略相结合。DGPF将物理模拟与数据驱动校正相结合，利用有限元建模和机器学习技术来捕捉复杂的土壤-隧道相互作用。ALIS策略通过结合实时监测数据、自适应参数校准和多保真度建模，提高了模型的适应性和效率。本研究引入了一个低功耗的铁路隧道沉降预测智能框架，利用TinyML来提高可扩展性和能源效率。通过动态地质力学预测框架（DGPF），将物理信息模拟与数据驱动校正相结合，该方法解决了沉降过程的非线性复杂性。与传统方法相比，该框架的预测误差降低35%，计算效率提高50%。实验结果证明了该方法在岩土工程安全关键场景下沉降实时监测的实用性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

Design of a low-power intelligent system for optimizing railway tunnel settlement data stream processing using TinyMLt

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Design of a low-power intelligent system for optimizing railway tunnel settlement data stream processing using TinyMLt

The advancement of TinyML technologies has opened new avenues for designing low-power intelligent systems, significantly enhancing the processing capabilities of embedded devices in critical infrastructure. To overcome these limitations, we propose a Dynamic Geomechanical Prediction Framework (DGPF) integrated with a novel Adaptive Learning-Informed Simulation (ALIS) strategy. The DGPF combines physics-informed simulations with data-driven corrections, leveraging finite element modeling and machine learning techniques to capture intricate soil-tunnel interactions. The ALIS strategy enhances model adaptability and efficiency by incorporating real-time monitoring data, adaptive parameter calibration, and multi-fidelity modeling. This study introduces a low-power intelligent framework for railway tunnel settlement prediction, leveraging TinyML to enhance scalability and energy efficiency. By integrating physics-informed simulations with data-driven corrections through a Dynamic Geomechanical Prediction Framework (DGPF), the proposed approach addresses the nonlinear complexities of settlement processes. The framework achieves a 35% reduction in prediction errors and a 50% improvement in computational efficiency compared to traditional methods. Experimental results demonstrate its practical applicability for real-time settlement monitoring in safety-critical geotechnical engineering scenarios.

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来源期刊

Computers & Electrical Engineering 工程技术-工程：电子与电气

CiteScore

9.20

自引率

7.00%

发文量

661

审稿时长

47 days

期刊介绍： The impact of computers has nowhere been more revolutionary than in electrical engineering. The design, analysis, and operation of electrical and electronic systems are now dominated by computers, a transformation that has been motivated by the natural ease of interface between computers and electrical systems, and the promise of spectacular improvements in speed and efficiency. Published since 1973, Computers & Electrical Engineering provides rapid publication of topical research into the integration of computer technology and computational techniques with electrical and electronic systems. The journal publishes papers featuring novel implementations of computers and computational techniques in areas like signal and image processing, high-performance computing, parallel processing, and communications. Special attention will be paid to papers describing innovative architectures, algorithms, and software tools.