Temporal Forecasting of Distributed Temperature Sensing in a Thermal Hydraulic System With Machine Learning and Statistical Models

IF 3.4 3区计算机科学 Q2 COMPUTER SCIENCE, INFORMATION SYSTEMS

IEEE Access Pub Date : 2025-01-13 DOI:10.1109/ACCESS.2025.3526438

Stella Pantopoulou;Matthew Weathered;Darius Lisowski;Lefteri H. Tsoukalas;Alexander Heifetz

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Abstract

We benchmark performance of long-short term memory (LSTM) network machine learning model and autoregressive integrated moving average (ARIMA) statistical model in temporal forecasting of distributed temperature sensing (DTS). Data in this study consists of fluid temperature transient measured with two co-located Rayleigh scattering fiber optic sensors (FOS) in a forced convection mixing zone of a thermal tee. We treat each gauge of a FOS as an independent temperature sensor. We first study prediction of DTS time series using Vanilla LSTM and ARIMA models trained on prior history of the same FOS that is used for testing. The results yield maximum absolute percentage error (MaxAPE) and root mean squared percentage error (RMSPE) of 1.58% and 0.06% for ARIMA, and 3.14% and 0.44% for LSTM, respectively. Next, we investigate zero-shot forecasting (ZSF) with LSTM and ARIMA trained on history of the co-located FOS only, which is advantageous when limited training data is available. The ZSF MaxAPE and RMSPE values for ARIMA are comparable to those of the Vanilla use case, while the error values for LSTM increase. We show that in ZSF, performance of LSTM network can be improved by training on most correlated gauges between the two FOS, which are identified by calculating the Pearson correlation coefficient. The improved ZSF MaxAPE and RMSPE for LSTM are 4.4% and 0.33%, respectively. Performance of ZSF LSTM can be further enhanced through transfer learning (TL), where LSTM is re-trained on a subset of the FOS that is the target of forecasting. We show that LSTM pre-trained on correlated dataset and re-trained on 30% of testing target dataset achieves MaxAPE and RMSPE values of 2.32% and 0.28%, respectively.

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基于机器学习和统计模型的热液压系统分布式温度传感时间预测

研究了长短期记忆（LSTM）网络机器学习模型和自回归综合移动平均（ARIMA）统计模型在分布式温度传感（DTS）时间预测中的性能。本研究的数据包括两个共置的瑞利散射光纤传感器（FOS）在热三通的强制对流混合区测量的流体温度瞬态。我们将FOS的每个仪表视为一个独立的温度传感器。我们首先使用香草LSTM和ARIMA模型来研究DTS时间序列的预测，这些模型是在用于测试的相同FOS的先前历史上训练的。结果表明，ARIMA的最大绝对百分比误差（MaxAPE）和均方根百分比误差（RMSPE）分别为1.58%和0.06%，LSTM的最大绝对百分比误差为3.14%和0.44%。接下来，我们研究了LSTM和ARIMA的零射击预测（zero-shot forecasting， ZSF），这两种预测方法只对同地FOS的历史进行训练，这在训练数据有限的情况下是有利的。ARIMA的ZSF MaxAPE和RMSPE值与Vanilla用例的值相当，而LSTM的错误值则增加了。我们发现，在ZSF中，LSTM网络的性能可以通过训练两个FOS之间的大多数相关指标来提高，这些指标通过计算Pearson相关系数来识别。LSTM的ZSF MaxAPE和RMSPE分别为4.4%和0.33%。通过迁移学习（TL）可以进一步提高ZSF LSTM的性能，其中LSTM是在作为预测目标的FOS子集上重新训练的。结果表明，LSTM在相关数据集上预训练，在30%的测试目标数据集上重新训练，MaxAPE和RMSPE值分别达到2.32%和0.28%。

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来源期刊

IEEE Access COMPUTER SCIENCE, INFORMATION SYSTEMSENGIN-ENGINEERING, ELECTRICAL & ELECTRONIC

CiteScore

9.80

自引率

7.70%

发文量

6673

审稿时长

6 weeks

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